2014 Cancer Facts & Figures

Cancer Facts
& Figures
2014
WA
38,230
MT
5,850
OR
22,530
ND
3,730
ID
7,990
WY
2,890
NV
14,450
CA
171,730
WI
32,480
SD
4,490
AZ
32,830
CO
23,810
NM
10,210
IL
66,840
KS
14,630
OK
19,830
MO
33,890
AK
3,750
AL
26,770
MA
37,940
RI
6,370
CT 22,070
NJ 51,130
WV
11,700
DE 5,320
VA
40,970
MD 30,680
DC 2,840
NC
52,550
TN
36,570
AR
16,520
PA
79,920
OH
67,000
KY
25,770
MS
15,740
TX
115,730
IN
35,560
ME
9,270
NY
107,200
MI
58,610
IA
17,630
NE
9,550
UT
10,780
VT
4,130
MN
29,340
NH
8,450
SC
26,390
GA
47,390
LA
24,300
FL
114,560
US
1,665,540
HI
6,640
PR
N/A
Estimated numbers of new cancer cases for 2014, excluding basal cell and squamous cell skin cancers and in situ carcinomas except urinary bladder.
Note: State estimates are offered as a rough guide and should be interpreted with caution. State estimates may not add to US total due to rounding.
Special Section:
Childhood & Adolescent
Cancers
see page 25
Contents
Basic Cancer Facts Age-adjusted Cancer Death Rates, Males by Site, US, 1930-2010* Age-adjusted Cancer Death Rates, Females by Site, US, 1930-2010* Estimated Number of New Cancer Cases and Deaths by Sex, US, 2014* Estimated Number of New Cases for Selected Cancers by State, US, 2014* Estimated Number of Deaths for Selected Cancers by State, US, 2014* Incidence Rates for Selected Cancers by State, US, 2006-2010* Death Rates for Selected Cancers by State, US, 2006-2010* 1
2
3
4
5
6
7
8
Selected Cancers Leading New Cancer Cases and Deaths – 2014 Estimates* Probability (%) of Developing Invasive Cancers during Selected Age Intervals by Sex, US, 2008-2010* Five-year Relative Survival Rates (%) by Stage at Diagnosis, 2003-2009* Trends in 5-year Relative Survival Rates (%) by Race, US, 1975-2009* 9
10
14
17
18
Special Section: Childhood & Adolescent Cancers 25
Tobacco Use Annual Number of Cancer Deaths Attributable to Smoking by Sex and Site, US, 2000-2004* 43
45
Cancer Disparities Cancer Incidence and Death Rates by Site, Race, and Ethnicity, US, 2006-2010* Geographic Patterns in Lung Cancer Death Rates by State, US, 2006-2010* 48
51
52
Nutrition and Physical Activity 53
Environmental Cancer Risk 55
The Global Fight against Cancer 57
The American Cancer Society 58
Sources of Statistics 66
Screening Guidelines for the Early Detection of Cancer in Average-risk Asymptomatic People* 68
*Indicates a figure or table
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©2014, American Cancer Society, Inc. All rights reserved,
including the right to reproduce this publication
or portions thereof in any form.
For written permission, address the Legal department of
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Atlanta, GA 30303-1002.
This publication attempts to summarize current scientific information about cancer.
Except when specified, it does not represent the official policy of the American Cancer Society.
Suggested citation: American Cancer Society. Cancer Facts & Figures 2014. Atlanta: American Cancer Society; 2014.
Basic Cancer Facts
What Is Cancer?
Cancer is a group of diseases characterized by the uncontrolled
growth and spread of abnormal cells. If the spread is not controlled, it can result in death. Cancer is caused by both external
factors (tobacco, infectious organisms, chemicals, and radiation) and internal factors (inherited mutations, hormones,
immune conditions, and mutations that occur from metabolism). These causal factors may act together or in sequence to
initiate or promote the development of cancer. Ten or more years
often pass between exposure to external factors and detectable
cancer. Cancer is treated with surgery, radiation, chemotherapy,
hormone therapy, immune therapy, and targeted therapy.
Can Cancer Be Prevented?
A substantial proportion of cancers could be prevented. All cancers caused by cigarette smoking and heavy use of alcohol could
be prevented completely. In 2014, almost 176,000 of the estimated 585,720 cancer deaths will be caused by tobacco use. In
addition, the World Cancer Research Fund has estimated that
up to one-third of the cancer cases that occur in economically
developed countries like the US are related to overweight or obesity, physical inactivity, and/or poor nutrition, and thus could
also be prevented. Certain cancers are related to infectious
agents, such as human papillomavirus (HPV), hepatitis B virus
(HBV), hepatitis C virus (HCV), human immunodeficiency virus
(HIV), and Helicobacter pylori (H. pylori). Many of these cancers
could be prevented through behavioral changes or the use of
protective vaccinations or antibiotic treatments. Many of the
more than 3 million skin cancer cases that are diagnosed annually could be prevented by protecting skin from excessive sun
exposure and avoiding indoor tanning.
Screening offers the ability for secondary prevention by detecting cancer early, before symptoms appear. Early detection
usually results in less extensive treatment and better outcomes.
Screening is known to reduce mortality for cancers of the breast,
colon, rectum, cervix, and lung (among heavy smokers).
A heightened awareness of changes in the breast, skin, or testicles may also result in detection of tumors at earlier stages.
Screening for colorectal and cervical cancers can actually prevent cancer by allowing for the detection and removal of
pre-cancerous lesions. For complete cancer screening guidelines, see page 68.
Who Is at Risk of Developing Cancer?
Anyone can develop cancer. Since the risk of being diagnosed
with cancer increases with age, most cases occur in adults who
are middle aged or older. About 77% of all cancers are diagnosed
in people 55 years of age and older. Cancer researchers use the
word “risk” in different ways, most commonly expressing risk as
lifetime risk or relative risk. In this publication, lifetime risk
refers to the probability that an individual will develop or die
from cancer over the course of a lifetime. In the US, men have
slightly less than a 1 in 2 lifetime risk of developing cancer; for
women, the risk is a little more than 1 in 3. It is important to note
that these probabilities are estimated based on the overall experience of the general population. Individuals within the
population may have higher or lower risk because of differences
in exposures (e.g., smoking), and/or genetic susceptibility.
Relative risk is a measure of the strength of the relationship
between a risk factor and cancer. It compares the risk of developing cancer in people with a certain exposure or trait to the risk
in people who do not have this characteristic. For example, male
smokers are about 23 times more likely to develop lung cancer
than nonsmokers, so their relative risk is 23. Most relative risks
are not this large. For example, women who have a first-degree
relative (mother, sister, or daughter) with a history of breast cancer are about twice as likely to develop breast cancer as women
who do not have this family history.
All cancers involve the malfunction of genes that control cell
growth and division. Only a small proportion of cancers are
strongly hereditary, in that an inherited genetic alteration confers a very high risk for developing cancer. Inherited factors play
a larger role in determining risk for some cancers (e.g., colorectal, breast, and prostate) than for others. It is now thought that
many familial cancers arise from the interplay between common gene variations and lifestyle/environmental risk factors.
However, most cancers do not result from inherited genes but
from damage to genes occurring during a person’s lifetime.
Genetic damage may result from internal factors, such as hormones or the metabolism of nutrients within cells, or external
factors, such as tobacco, or excessive exposure to chemicals,
sunlight, or ionizing radiation.
How Many People Alive Today Have Ever Had
Cancer?
Approximately 13.7 million Americans with a history of cancer
were alive on January 1, 2012. Some of these individuals were
cancer free, while others still had evidence of cancer and may
have been undergoing treatment.
How Many New Cases Are Expected to Occur
This Year?
About 1,665,540 new cancer cases are expected to be diagnosed
in 2014. This estimate does not include carcinoma in situ (noninvasive cancer) of any site except urinary bladder, nor does it
include basal cell or squamous cell skin cancers, which are not
required to be reported to cancer registries.
Cancer Facts & Figures 2014 1
How Many People Are Expected to Die of
Cancer This Year?
Although relative survival for specific cancer types provides
some indication about the average survival experience of cancer
patients in a given population, it may not predict individual
prognosis and should be interpreted with caution. First, 5-year
relative survival rates for the most recent time period are based
on patients who were diagnosed from 2003 to 2009 and thus do
not reflect the most recent advances in detection and treatment.
Second, factors that influence survival, such as treatment protocols, other illnesses, and biological or behavioral differences in
individual cancers or people, cannot be taken into account in
the estimation of relative survival rates. For more information
about survival rates, see Sources of Statistics on page 66.
In 2014, about 585,720 Americans are expected to die of cancer,
almost 1,600 people per day. Cancer is the second most common
cause of death in the US, exceeded only by heart disease,
accounting for nearly 1 of every 4 deaths.
What Percentage of People Survive Cancer?
The 5-year relative survival rate for all cancers diagnosed
between 2003 and 2009 is 68%, up from 49% in 1975-1977 (see
page 17). The improvement in survival reflects both progress in
diagnosing certain cancers at an earlier stage and improvements in treatment. Survival statistics vary greatly by cancer
type and stage at diagnosis. Relative survival compares survival
among cancer patients to that of people not diagnosed with cancer who are the same age, race, and sex. It represents the
percentage of cancer patients who are alive after some designated time period (usually 5 years) relative to people without
cancer. It does not distinguish between patients who are cancerfree and those who have relapsed or are still in treatment. While
5-year relative survival is useful in monitoring progress in the
early detection and treatment of cancer, it does not represent the
proportion of people who are cured because cancer deaths can
occur beyond 5 years after diagnosis.
How Is Cancer Staged?
Staging describes the extent or spread of cancer at the time of
diagnosis. Proper staging is essential in determining the choice
of therapy and in assessing prognosis. A cancer’s stage is based
on the size or extent of the primary (main) tumor and whether it
has spread to nearby lymph nodes or other areas of the body. A
number of different staging systems are used to classify cancer.
A system of summary staging is used for descriptive and statistical analysis of tumor registry data. If cancer cells are present
only in the layer of cells where they developed and have not
spread, the stage is in situ. If cancer cells have penetrated beyond
Age-adjusted Cancer Death Rates*, Males by Site, US, 1930-2010
100
Lung & bronchus
Rate per 100,000 male population
80
60
Stomach
Prostate
Colon & rectum
40
20
Leukemia
Pancreas
Liver
0
1930
1935
1940
1945
1950
1955
1960
1965
1970
1975
1980
1985
1990
1995
2000
2005
2010
*Per 100,000, age adjusted to the 2000 US standard population.
Note: Due to changes in ICD coding, numerator information has changed over time. Rates for cancer of the liver, lung and bronchus, and colon and rectum are affected
by these coding changes.
Source: US Mortality Volumes 1930 to 1959 and US Mortality Data 1960 to 2010, National Center for Health Statistics, Centers for Disease Control and Prevention.
©2014, American Cancer Society, Inc., Surveillance Research
2 Cancer Facts & Figures 2014
comparable to those published in Cancer Facts & Figures prior to
2012 because in 2011, the NIH began calculating these estimates
using a different data source: the Medical Expenditure Panel
Survey (MEPS) of the Agency for Healthcare Research and Quality. The MEPS estimates are based on more current, nationally
representative data and are used extensively in scientific publications. As a result, direct and indirect costs will no longer be
projected to the current year, and estimates of indirect morbidity costs have been discontinued. For more information, visit
nhlbi.nih.gov/about/factpdf.htm.
the original layer of tissue, the cancer has become invasive and
is categorized as local, regional, or distant stage based on the
extent of spread. (For a more detailed description of these categories, see the footnotes in the table Five-year Relative Survival
Rates (%) by Stage at Diagnosis, 2003-2009 on page 17.) For most
cancers, clinicians use a different staging system called TNM,
which assesses cancer growth and spread in three ways: extent
of the primary tumor (T), absence or presence of regional lymph
node involvement (N), and absence or presence of distant metastases (M). Once the T, N, and M categories are determined, a
stage of 0, I, II, III, or IV is assigned, with stage 0 being in situ,
stage I being early, and so on, with stage IV being the most
advanced disease. Some cancers (e.g., lymphoma) have alternative staging systems. As the molecular properties of cancer have
become better understood, tumor biological markers and
genetic features have been incorporated into prognostic models,
treatment plans, and/or stage for some cancer sites.
Lack of health insurance and other barriers prevent many Americans from receiving optimal health care. According to the US
Census Bureau, approximately 48.6 million Americans (15.7%)
were uninsured in 2011, including one in three Hispanics and
one in 10 children (18 years of age and younger). Uninsured
patients and those from ethnic minorities are substantially
more likely to be diagnosed with cancer at a later stage, when
treatment can be more extensive and more costly. The Affordable Care Act is expected to substantially reduce the number of
people who are uninsured and improve the health care system
for cancer patients. For more information on the relationship
between health insurance and cancer, see Cancer Facts & Figures 2008, Special Section, available online at cancer.org/
statistics.
What Are the Costs of Cancer?
The National Institutes of Health (NIH) estimates that the overall costs of cancer in 2009 were $216.6 billion: $86.6 billion for
direct medical costs (total of all health expenditures) and $130.0
billion for indirect mortality costs (cost of lost productivity due
to premature death). PLEASE NOTE: These numbers are not
Age-adjusted Cancer Death Rates*, Females by Site, US, 1930-2010
100
Rate per 100,000 female population
80
60
Lung & bronchus
Uterus†
40
Breast
20
Colon & rectum
Stomach
Pancreas
Ovary
0
1930
1935
1940
1945
1950
1955
1960
1965
1970
1975
1980
1985
1990
1995
2000
2005
2010
*Per 100,000, age adjusted to the 2000 US standard population. †Uterus refers to uterine cervix and uterine corpus combined.
Note: Due to changes in ICD coding, numerator information has changed over time. Rates for cancer of the lung and bronchus, colon and rectum, and ovary are affected
by these coding changes.
Source: US Mortality Volumes 1930 to 1959 and US Mortality Data 1960 to 2010, National Center for Health Statistics, Centers for Disease Control and Prevention.
©2014, American Cancer Society, Inc., Surveillance Research
Cancer Facts & Figures 2014 3
Estimated Number* of New Cancer Cases and Deaths by Sex, US, 2014
Estimated New Cases
Estimated Deaths
Both Sexes
Male
Female
Both Sexes
Male
Female
1,665,540
855,220
810,320
585,720
310,010
275,710
42,440
13,590
11,920
14,410
2,520
30,220
9,720
7,150
11,550
1,800
12,220
3,870
4,770
2,860
720
8,390
2,150
2,070
2,540
1,630
5,730
1,450
1,130
1,900
1,250
2,660
700
940
640
380
Digestive system
Esophagus
Stomach
Small intestine
Colon† Rectum
Anus, anal canal, & anorectum
Liver & intrahepatic bile duct
Gallbladder & other biliary
Pancreas
Other digestive organs
289,610
18,170
22,220
9,160
96,830
40,000
7,210
33,190
10,650
46,420
5,760
162,730
14,660
13,730
4,880
48,450
23,380
2,660
24,600
4,960
23,530
1,880
126,880
147,260
84,970
3,510
15,450
12,450
8,490
10,990
6,720
4,280
1,210
640
48,380
50,310
26,270
16,620
4,550
950
370
8,590
23,000
15,870
5,690
3,630
1,610
22,890
39,590
20,170
3,880
2,130
870
62,290
3,000
4,270
570
24,040
Respiratory system
Larynx
Lung & bronchus
Other respiratory organs
242,550
12,630
224,210
5,710
130,000
10,000
116,000
4,000
112,550
2,630
108,210
1,710
163,660
3,610
159,260
790
73,380
740
72,330
310
All Sites
Oral cavity & pharynx
Tongue
Mouth
Pharynx
Other oral cavity
Bones & joints
90,280
2,870
86,930
480
580
7,130
2,020
19,420
1,260
3,020
1,680
1,340
1,460
830
630
Soft tissue (including heart)
12,020
6,550
5,470
4,740
2,550
2,190
Skin (excluding basal & squamous)
Melanoma-skin
Other nonepithelial skin
81,220
76,100
5,120
46,630
43,890
2,740
34,590
32,210
2,380
12,980
9,710
3,270
8,840
6,470
2,370
4,140
3,240
900
Breast
235,030 2,360 232,670
Genital system
Uterine cervix
Uterine corpus
Ovary
Vulva
Vagina & other genital, female
Prostate
Testis
Penis & other genital, male
338,450
243,460
94,990
58,970
30,180
28,790
12,360
12,360
4,020
4,020
52,630
52,630
8,590
8,590
21,980
21,980
14,270
14,270
4,850
4,850
1,030
1,030
3,170
3,170
880
880
233,000
233,000
29,480
29,480
8,820
8,820
380
380
1,640
1,640
320
320
Urinary system
Urinary bladder
Kidney & renal pelvis
Ureter & other urinary organs
141,610
74,690
63,920
3,000
Eye & orbit
97,420
56,390
39,140
1,890
44,190
18,300
24,780
1,110
40,430
30,350
15,580
13,860
910
43040,000
20,610
11,170
8,900
540
9,740
4,410
4,960
370
2,730
1,440
1,290
310
130
180
Brain & other nervous system
23,380
12,820
10,560
14,320
8,090
6,230
Endocrine system
Thyroid
Other endocrine
65,630
62,980
2,650
16,600
15,190
1,410
49,030
47,790
1,240
2,820
1,890
930
1,300
830
470
1,520
1,060
460
Lymphoma
Hodgkin lymphoma
Non-Hodgkin lymphoma
79,99043,340 36,650
9,190
5,070
4,120
70,800
38,270
32,530
20,170 11,140 9,030
1,180
670
510
18,990
10,470
8,520
Myeloma
24,05013,500 10,550
11,090 6,110 4,980
Leukemia
Acute lymphocytic leukemia
Chronic lymphocytic leukemia
Acute myeloid leukemia
Chronic myeloid leukemia
Other leukemia‡
52,38030,100 22,280 24,09014,04010,050
6,020
3,140
2,880
1,440
810
630
15,720
9,100
6,620
4,600
2,800
1,800
18,860
11,530
7,330
10,460
6,010
4,450
5,980
3,130
2,850
810
550
260
5,8003,200 2,600
6,7803,870 2,910
Other & unspecified primary sites‡31,430
16,370
15,060
44,680
24,780
19,900
*Rounded to the nearest 10; estimated new cases exclude basal cell and squamous cell skin cancers and in situ carcinomas except urinary bladder. About 62,570 carcinoma in situ of the female breast and 63,770 melanoma in situ will be newly diagnosed in 2014. † Estimated deaths for colon and rectal cancers are combined. ‡ More
deaths than cases may reflect lack of specificity in recording underlying cause of death on death certificates and/or an undercount in the case estimate.
Source: Estimated new cases are based on 1995-2010 incidence rates reported by the North American Association of Central Cancer Registries, representing 89% of the
US population. Estimated deaths are based on 1995-2010 US mortality data, National Center for Health Statistics, Centers for Disease Control and Prevention.
©2014, American Cancer Society, Inc., Surveillance Research
4 Cancer Facts & Figures 2014
Estimated Number* of New Cases for Selected Cancers by State, US, 2014
Melanoma
Non
Female Uterine Colon & Uterine
Lung &
of the Hodgkin
Urinary
State
All Sites
Breast
Cervix
Rectum Corpus Leukemia Bronchus
Skin Lymphoma Prostate Bladder
Alabama
Alaska
Arizona
Arkansas
California
26,770 3,660 210 2,350 650 690 4,1601,320 9903,760 990
3,750450 † 280100 100 430 90 140 530150
32,830 4,520 210 2,560 910 950 4,280 1,430 1,320 4,3901,490
16,520 2,050 140 1,500 400 480 2,660 490 6602,240 640
171,730 26,1301,550 13,930 5,650 5,650 18,780 8,440 7,77023,010 7,210
Colorado
Connecticut
Delaware
Dist. of Columbia
Florida
23,810 3,780 160 1,720 750 870 2,540 1,400 1,060 3,6801,040
22,070 3,160 120 1,650 790 610 2,730 1,090 920 3,1201,170
5,320760 † 420180 150 790 290 220 800260
2,840
430
† 250100 60 320 80 100 510 80
114,560 15,480 960 10,230 3,410 3,810 17,960 5,320 5,05016,5905,800
Georgia
Hawaii
Idaho
Illinois
Indiana
47,390 7,010 420 3,9401,3101,370 6,540 2,1801,820 7,6001,710
6,6401,090 60 700 270 220 890 410 300 810250
7,990 1,100 50 610 230 290 960 450 3601,320 390
66,840 9,230 470 5,5302,290 2,180 9,100 2,440 2,890 8,8203,090
35,560 4,590 260 3,0201,070 1,060 5,540 1,550 1,480 4,3901,600
Iowa
Kansas
Kentucky
Louisiana
Maine
17,630 2,320 100 1,580 610 640 2,330 980 8002,340 830
14,630 2,090 100 1,120 470 490 1,900 780 6501,980 620
25,770 3,370 200 2,170 720 790 4,690 1,5401,070 3,2801,100
24,3003,1602002,270540 7203,470 750 9603,720940
9,270 1,220 50 700 340 310 1,400 440 3801,160 540
Maryland
30,680 4,570 230 2,5001,020 800 3,990 1,400 1,210 5,0001,280
Massachusetts 37,940 5,560 200 2,8001,320 1,140 4,930 1,800 1,600 5,6002,030
Michigan
58,610 7,660 340 4,5702,010 1,830 8,090 2,8302,500 8,7402,930
Minnesota
29,340 3,820 130 2,240 9501,050 3,070 1,0301,240 3,8701,220
Mississippi
15,740 2,130 140 1,510 360 410 2,420 560 5602,210 540
Missouri
Montana
Nebraska
Nevada
New Hampshire
New Jersey
New Mexico
New York
North Carolina
North Dakota
Ohio
Oklahoma
Oregon
Pennsylvania
Rhode Island
South Carolina
South Dakota
Tennessee
Texas
Utah
Vermont
Virginia
Washington
West Virginia
Wisconsin
Wyoming
33,890 4,610 240 2,9701,090 1,040 5,370 1,510 1,430 4,0101,530
5,850860 † 500 180 200 760 290 2601,010 300
9,550 1,360 60 880 320 330 1,220 460 4401,250 430
14,450 1,880 120 1,290 350 440 2,040 470 5501,890 680
8,450
1,150
† 600 300 250 1,110 400 3501,160 460
51,130
10,210
107,200
52,550
3,730
7,290
1,450
15,230
7,580
510
380
4,280
1,820
1,560
6,130
2,590
2,250
7,320
2,510
80
830
300
370
1,060
470
400
1,400
400
850
8,590
4,040
3,460
13,720
4,240
4,720
15,440
5,330
380
4,230
1,570
1,550
7,850
2,540
2,110
7,580
2,170
† 350 110 130 400 160 160 460180
67,000 8,710 400 5,4502,280 1,890 9,760 3,170 2,860 8,690 3,110
19,830 2,700 160 1,760 530 660 3,320 650 8502,570 830
22,530 3,320 130 1,540 720 640 2,950 1,440 960 3,2001,080
79,920 10,660 500 6,7902,840 2,420 10,290 3,820 3,42010,930 4,070
6,370
870
† 500230 180 870 260 250 840340
26,390
3,750
210
2,200
750
790
4,130
1,350
1,030
4,000
1,100
4,490
600
† 410150 160 540 200200 590210
36,570 4,840 290 3,030 9301,040 5,980 1,9101,470 4,6701,510
115,730 16,080 1,140 9,760 3,130 4,190 14,890 3,420 5,03015,900 4,190
10,780 1,440 60 650 350 390 650 770 4901,780 420
4,130560 † 290140 110 550 220 160 580210
40,970 6,170 290 3,2801,300 1,080 5,580 2,130 1,640 6,3301,700
38,230 5,620 230 2,6701,1601,250 4,630 2,410 1,710 5,3801,730
11,700
1,350
90
1,060
380
330
2,090
540
480
1,450
570
32,480 4,330 190 2,520 1,140 1,150 4,020 1,440 1,410 4,6301,580
2,890420 † 240 90 90 330 150 120 490140
United States 1,665,540 232,67012,360136,83052,63052,380 224,210 76,10070,800233,00074,690
*Rounded to the nearest 10. Excludes basal cell and squamous cell skin cancers and in situ carcinomas except urinary bladder. † Estimate is fewer than 50 cases.
Note: These estimates are offered as a rough guide and should be interpreted with caution. State estimates may not sum to US total due to rounding and exclusion of
state estimates fewer than 50 cases.
©2014, American Cancer Society, Inc., Surveillance Research
Cancer Facts & Figures 2014 5
Estimated Number* of Deaths for Selected Cancers by State, US, 2014
Brain/
Non-
Nervous Female
Colon &
Lung &
Hodgkin
State
All Sites System
Breast
Rectum Leukemia
Liver
Bronchus Lymphoma Ovary Pancreas Prostate
Alabama
Alaska
Arizona
Arkansas
California
10,510 270 690 950 410 350 3,310 310 280 630540
990
†
70
90
†
†
270
†
†
60
60
11,400 310 780 990 500 4702,840 390 310 790640
6,730 150 420 620 270 2102,200 200 140 400310
57,950 1,590 4,270 5,150 2,510 3,140 12,590 2,000 1,560 4,1503,380
Colorado
Connecticut
Delaware
Dist. of Columbia
Florida
7,480240 530 6703303001,720240240510450
6,880 180 470 460 290 250 1,760 220 180 520390
1,980
†
120
160
70
90
600
60
50
130
90
1,010
†
80
100
†
60
230
†
†
80
80
42,740 920 2,770 3,560 1,760 1,620 12,050 1,430 9402,8902,170
Georgia
Hawaii
Idaho
Illinois
Indiana
16,320 380 1,220 1,480 620 590 4,690 460 4301,040 800
2,450
†
140
230
90
140
580
80
60
210
120
2,730 80 180 210 130 80 670 90 60 210180
24,020 540 1,610 2,190 1,020 810 6,570 780 560 1,6101,190
13,3703108601,0905503804,140440310840580
Iowa
Kansas
Kentucky
Louisiana
Maine
6,380190 390
5,460 150 370
10,130 210 590
9,040 200 640
3,300 90 190
570280 1901,780230180410330
480 260 1701,560 200 140 370250
850 370 280 3,570 300 200 570390
840 330 400 2,650 260 190 600400
250 130 110 970 100 60 200160
Maryland
10,500 240 820 890 390 4002,760 300 270 760550
Massachusetts12,810 310 790 990 510 5503,500 400 320 920630
Michigan
20,800 550 1,400 1,680 910 710 5,990 720 4801,480 890
Minnesota
9,750260 620 780460 3602,480340240650540
Mississippi
6,350 140 420 640 250 2401,990 180 120 380330
Missouri
Montana
Nebraska
Nevada
New Hampshire
12,870 310
2,000 50
3,480 100
4,790 140
2,670
70
New Jersey
New Mexico
New York
North Carolina
North Dakota
16,350
3,600
34,440
18,980
1,270
Ohio
Oklahoma
Oregon
Pennsylvania
Rhode Island
25,260 600 1,720 2,140 990
7,980 200 510 690 320
7,940 230 510 660 320
28,670 610 1,940 2,490 1,200
2,140
50
130
160
90
350
90
790
410
†
9101,090 540
130 170 90
210 340 140
380 480 190
170
200
100
1,290
260
2,390
1,310
90
1,510
350
2,970
1,500
130
630
140
1,440
720
60
4503,950 390
50 520 70
100 900 130
220 1,420 140
80
750
80
600
170
1,470
660
†
3,970
790
8,790
5,700
310
510
110
1,110
560
†
250 860550
60 130130
80 240200
100 370280
60
190
130
440
90
910
430
†
790 7,370 810
2802,440 270
3402,090 280
980 7,600 1,010
80
580
60
1,220
240
2,540
1,190
80
760
220
1,760
920
80
570 1,7301,200
180 470370
220 550440
730 1,9901,370
50
130
100
South Carolina 9,950220 670 840 360 3702,970 280 230 610510
South Dakota
1,610
50
110
150
70
50
440
50
†
110
90
Tennessee
14,280 350 9101,220 540 5004,630 440 290 820630
Texas
37,830 950 2,700 3,430 1,530 2,080 9,600 1,230 900 2,4401,660
Utah
2,870 110 270 250 150 100 460 120 80 240210
Vermont
Virginia
Washington
West Virginia
Wisconsin
Wyoming
United States
1,340
†
80
100
14,750 350 1,090 1,240
12,550380 820 970
4,680
100
270
420
11,360 310 710 860
990
†
60
90
585,720
14,320
40,000
50,310
50
570
540
170
550
70
24,090
60
390
520 4,110
5503,270
120
1,480
3903,000
†
250
23,000
159,260
†
460
430
160
400
†
18,990
†
90
70
3801,010 730
360 880730
100
230
190
300 800630
†
80
40
14,270
39,590
29,480
*Rounded to nearest 10. † Estimate is fewer than 50 deaths.
Note: These estimates are offered as a rough guide and should be interpreted with caution. State estimates may not sum to US total due to rounding and exclusion of
state estimates fewer than 50 deaths.
©2014, American Cancer Society, Inc., Surveillance Research
6 Cancer Facts & Figures 2014
Incidence Rates* for Selected Cancers by State, US, 2006-2010
All Sites
Breast
Colon & Rectum
Lung & Bronchus
Non-Hodgkin
Lymphoma
Prostate
Urinary
Bladder
State
MaleFemale Female MaleFemale MaleFemale MaleFemale
Male
MaleFemale
Alabama
Alaska
Arizona
Arkansas†‡
California
573.2395.2
521.0430.3
441.4371.2
557.7388.1
505.7397.1
118.7 57.2 40.3 103.2 54.0 19.5 13.6
127.7 53.1 44.5 83.8 60.4 21.8 16.1
110.2 41.4 32.0 61.8 47.9 18.0 13.4
110.3 55.6 40.5 108.4 60.4 21.2 15.3
122.0 49.4 37.3 60.4 44.4 22.9 15.6
157.7
137.3
112.7
156.4
140.3
33.3
38.0
32.2
33.9
33.5
7.5
9.8
8.4
8.1
8.0
Colorado
Connecticut
Delaware
Dist. of Columbia
Florida
483.1396.4
576.2456.9
601.7443.3
574.8 427.7
518.8399.9
125.3
136.3
126.5
139.7
114.3
15.9
17.3
16.7
13.4
15.2
142.7
160.0
177.3
194.4
131.2
31.2
46.8
43.2
25.1
35.3
8.2
12.6
11.3
9.0
8.6
Georgia
Hawaii
Idaho
Illinois
Indiana
568.7403.1 121.5 52.1 38.4 93.3 55.0 21.5 14.8
484.4393.4 123.1 56.9 38.0 64.3 38.7 20.7 13.7
513.3410.1 119.5 43.2 34.8 61.5 47.2 21.3 17.5
566.6440.3 126.4 59.1 43.4 86.7 60.9 24.0 16.4
527.4422.0 117.4 54.7 41.8 96.4 63.5 23.3 17.0
165.7
119.9
152.9
153.9
122.4
33.9
25.8
36.1
39.4
35.2
7.9
6.3
8.9
9.9
8.8
Iowa
Kansas
Kentucky
Louisiana
Maine
555.7437.1
552.2422.0
611.2462.4
603.4413.6
581.5460.6
137.2
152.4
134.6
169.3
144.8
41.7 8.8
37.9 9.3
40.5 9.7
34.1 8.1
48.0 13.2
Maryland
Massachusetts
Michigan
Minnesota§
Mississippi
529.1415.0 128.0 47.6 36.7 74.4 55.8 21.3 15.0
568.1460.4 134.2 49.9 38.8 78.3 64.1 25.0 16.5
574.1433.5 120.0 51.0 39.3 86.1 61.6 24.9 17.7
------ ------------
------
---
598.6396.9 113.8 61.3 44.7 112.7 56.2 21.6 14.5
157.2 33.4 9.2
153.6 43.9 11.9
163.7 41.3 10.7
------
--166.3 30.8 7.2
Missouri
Montana
Nebraska
Nevada†¶
New Hampshire
530.8423.3
520.8421.9
526.2420.9
509.8399.2
580.3 452.1
121.5
124.1
122.3
112.7
132.0
55.3
51.1
57.7
52.0
46.7
40.8
39.0
44.4
38.1
38.0
95.6
68.9
74.6
75.7
80.1
64.3
56.3
51.2
64.7
62.2
22.3
22.8
23.5
20.4
25.1
16.0
15.0
17.7
15.3
17.1
126.2
155.2
143.0
138.9
155.4
34.8 8.4
36.4 9.9
35.0 8.6
37.3 10.7
49.1
13.2
New Jersey
New Mexico
New York North Carolina North Dakota
582.6
461.9
585.4
564.9
528.6
129.3
108.8
127.7
124.9
123.0
54.7
44.1
53.3
50.8
59.2
41.2
33.6
40.9
37.1
41.8
72.8
52.9
76.3
96.7
68.1
55.3
38.1
56.0
57.2
43.3
25.2
18.2
26.3
22.6
22.0
17.8
13.8
18.1
15.7
18.4
169.2
134.1
167.3
151.9
156.2
43.6
26.2
42.1
37.5
38.6
Ohio†¶
Oklahoma
Oregon
Pennsylvania
Rhode Island
548.1425.4
552.2422.0
508.8429.2
573.6454.8
575.7 462.4
120.5
121.7
129.5
126.0
131.0
55.5
53.6
45.5
56.0
51.3
42.2
40.8
36.8
42.8
41.3
92.6 60.7 23.0 16.1
96.1 62.7 22.4 17.1
70.6 57.6 22.8 15.3
84.4 57.9 25.2 17.8
84.1
64.5
22.5
17.9
145.2
148.4
139.3
149.5
148.9
38.7 9.6
34.7 8.6
37.1 9.5
44.1 11.0
48.7
13.8
South Carolina
South Dakota
Tennessee
Texas Utah
551.7 401.1
499.4 395.9
562.0416.0
513.9 389.9
494.8357.7
122.3
117.9
118.8
114.4
110.8
50.3
55.7
53.4
50.9
39.4
37.9
41.8
40.4
35.7
31.2
94.1
53.9
73.8
48.0
103.4 61.3
78.2
49.0
34.1 23.3
20.5
21.6
22.6
22.2
25.2
13.4
15.9
16.3
15.9
16.3
152.8
145.5
144.3
133.2
175.9
30.8
33.6
35.4
29.5
31.4
Vermont
Virginia†
Washington
West Virginia
Wisconsin
Wyoming
539.8453.8
521.7397.4
544.6437.7
557.7 434.1
530.8419.2
497.1384.2
131.4
124.5
131.0
110.2
122.5
110.8
44.8
46.9
46.1
58.0
48.4
47.5
38.3
36.7
36.3
43.8
37.5
37.7
81.2 65.6
82.2 53.9
72.1 57.3
106.4
70.0
73.6 53.4
57.3 46.0
24.1
21.7
26.2
23.2
24.3
19.8
17.7
14.2
17.4
17.5
17.3
15.0
139.9
150.3
151.6
131.8
142.9
152.2
40.5 12.2
33.3 8.3
38.9 9.3
38.8
10.7
39.2 9.7
38.7 9.9
United States
542.3
122.2
51.7
39.1
23.3
16.3
146.6
36.9
450.6
362.5
449.2
416.0
410.2
418.8
123.4
123.2
121.3
119.7
126.5
43.6
51.3
53.1
50.9
47.8
56.9
55.0
63.9
62.4
51.4
33.6 56.1 44.2
39.2 75.5 59.5
39.6 87.1 65.8
44.8
77.5
48.1
36.6 79.4 56.7
44.3
39.9
46.0
44.0
41.2
84.7 54.9
80.2 54.5
125.9 80.3
99.6 57.7
91.5 67.3
80.0
55.1
22.5
25.2
23.7
21.8
21.9
26.8
23.4
25.3
24.5
25.4
18.9
16.8
17.5
16.5
17.9
11.6
6.2
10.6
8.9
9.2
8.4
8.3
8.2
6.9
5.3
9.1
*Per 100,000, age adjusted to the 2000 US standard population. † This state’s data are not included in US combined rates because they did not meet high-quality standards for one or more years during 2006-2010 according to the North American Association of Central Cancer Registries (NAACCR). ‡ Rates are based on incidence data
for 2006-2008. §This state’s registry did not submit 2006-2010 cancer incidence data to NAACCR. ¶ Rates are based on incidence data for 2006-2009.
Source: NAACCR, 2013. Data are collected by cancer registries participating in the National Cancer Institute’s SEER program and the Centers for Disease Control and
Prevention’s National Program of Cancer Registries.
American Cancer Society, Surveillance Research, 2014
Cancer Facts & Figures 2014 7
Death Rates* for Selected Cancers by State, US, 2006-2010
All Sites
Breast
Colon & Rectum
Lung & Bronchus
Non-Hodgkin
Lymphoma
Pancreas
Prostate
State
Male Female Female Male Female MaleFemale MaleFemale Male Female Male
Alabama
Alaska
Arizona
Arkansas
California
255.4156.4
210.5161.0
186.0131.7
250.6160.9
189.8139.8
23.3 22.5 15.0
24.2 19.6 15.1
20.6 17.1 11.9
23.4 22.7 15.6
21.9 17.5 12.7
87.4 40.8
61.8 45.8
49.8 33.2
90.1 45.4
47.2 32.3
8.0
7.6
7.6
8.6
7.8
5.3
5.5
4.8
5.5
4.9
13.2
12.9
11.4
13.2
11.7
9.7
9.8
8.3
9.6
9.4
28.9
22.5
20.5
25.3
22.3
Colorado
Connecticut
Delaware
Dist. of Columbia
Florida
181.4133.2
199.5144.7
228.0159.3
248.5
167.6
204.5140.7
19.6
21.6
22.8
29.8
21.3
16.7
16.2
20.4
22.2
18.1
12.4
12.1
13.3
18.9
12.8
44.2 31.3
52.7 38.2
68.2 47.7
61.9
35.0
61.4 38.8
7.8
7.5
8.3
8.0
7.8
4.4
4.9
4.8
4.0
4.9
10.8
13.9
13.0
16.9
12.1
9.0
9.9
9.5
12.0
8.8
22.9
22.3
23.7
38.8
20.1
Georgia
Hawaii
Idaho
Illinois
Indiana
228.3147.8
178.4117.1
192.9140.2
223.3158.5
238.8161.5
23.4
16.4
21.6
23.6
23.9
20.2 13.8
17.3 10.9
16.1 12.4
21.7 15.4
21.3 14.5
73.1 38.7
48.825.9
49.2 34.5
65.8 41.9
79.4 46.7
7.6
7.2
7.2
8.5
9.3
4.5
4.3
5.6
5.3
5.4
12.5 9.1
12.3 9.7
12.0 9.2
13.0 10.1
13.0 9.4
27.1
15.7
25.9
24.3
23.2
Iowa
Kansas
Kentucky
Louisiana
Maine
212.6148.4
214.4146.5
262.7173.3
254.7164.4
231.1158.3
21.3
22.2
23.1
25.4
20.9
20.0
20.6
23.4
24.0
20.2
15.2
13.1
16.2
15.7
13.9
64.1 38.3
66.8 39.4
97.1 55.8
80.9 43.6
69.9 46.0
8.9
9.1
9.0
8.6
8.8
5.5
5.3
5.7
5.2
5.1
12.2
12.6
12.7
14.2
11.6
8.8
9.1
9.6
11.1
9.8
22.7
20.7
23.9
26.6
22.9
Maryland
Massachusetts
Michigan
Minnesota
Mississippi
216.9154.0
216.6152.5
223.0159.5
203.9145.0
270.6159.1
24.5 20.5 14.0
21.3 18.7 13.4
24.0 19.4 14.2
20.9 17.6 12.6
24.7 24.8 16.5
61.7 40.8
60.6 42.1
68.2 43.9
53.3 37.0
95.4 42.0
7.4
7.8
8.9
9.4
8.3
4.5
4.8
5.8
5.2
4.7
12.9
12.7
13.9
11.9
14.1
10.3
10.4
10.2
9.3
10.1
25.0
22.4
21.8
23.9
31.2
Missouri
Montana
Nebraska
Nevada
New Hampshire
231.1160.2
24.2 21.2 14.6 76.5 46.2 8.3 5.4 13.0 9.9
21.8
195.3145.1
19.8 16.7 14.0 52.1 39.6
7.9 4.9 11.8 8.4
26.4
208.4
143.820.121.4
15.060.3
35.58.4
5.712.0
9.722.9
211.4153.6
23.0 21.0 14.9 59.7 46.5
7.1 4.6 12.6 9.7
23.9
211.7 154.2
21.3
17.9
13.1
59.0
43.3
7.3
4.7
13.2
10.4
22.4
New Jersey
New Mexico
New York
North Carolina
North Dakota
207.8
187.4
199.7
232.2
203.6
Ohio
Oklahoma
Oregon
Pennsylvania
Rhode Island
154.3
131.6
145.4
149.9
137.2
25.2
20.9
22.3
23.1
21.6
21.0
18.8
19.2
19.4
21.2
14.9
12.7
13.8
13.1
13.9
55.8
43.4
54.3
76.6
54.1
236.5162.6
238.8161.0
208.5153.4
225.6157.0
221.8 149.6
24.8
23.9
21.6
23.8
20.8
21.8
22.1
18.1
21.5
18.6
15.2
14.5
13.3
15.0
13.2
South Carolina
South Dakota
Tennessee
Texas
Utah
240.1
151.7
206.8
141.3
256.4160.4
209.3141.8
157.1112.3
23.5
20.3
23.3
21.8
21.8
Vermont
Virginia
Washington
West Virginia
Wisconsin
Wyoming
212.0154.3
221.1151.4
207.2152.2
246.9 168.6
213.7149.7
196.0146.8
United States
215.3
149.7
7.8
6.6
7.9
7.5
6.7
5.2
4.5
4.9
5.0
5.1
13.4
10.9
12.8
12.0
12.6
10.1
8.4
9.9
9.6
8.3
21.6
24.4
21.8
25.8
23.6
74.8 44.2
79.6 46.6
58.4 42.7
65.8 39.6
64.9
42.6
9.2
9.0
8.5
8.9
8.3
5.6
6.0
5.3
5.5
4.4
13.1
12.2
12.3
13.4
12.2
10.1
8.9
9.9
10.0
8.9
23.8
23.5
24.4
22.7
20.6
20.2
14.2
19.8
13.9
21.8 15.3
20.0 13.1
14.3 10.7
77.1
39.9
61.9
34.1
89.5 46.6
60.7 35.4
27.516.8
7.8
7.8
9.2
7.9
7.7
4.7
5.3
5.4
4.9
4.7
12.7
11.1
13.1
11.8
10.0
9.8
9.3
9.4
8.8
8.4
27.5
23.4
25.2
21.3
25.9
20.4
24.0
21.5
22.1
21.3
21.3
17.4 14.8
19.2 14.0
17.1 12.5
23.4
16.1
18.0 12.7
18.7 14.7
62.3 45.1
67.1 40.0
57.0 42.1
84.3
50.9
58.4 38.4
49.9 36.4
7.8
8.2
8.6
8.7
9.0
7.6
5.0
4.8
5.4
6.6
5.5
5.3
12.4 9.3
12.7 9.7
12.7 10.0
11.3
7.8
12.8 10.0
12.9 9.0
22.1
24.7
24.2
20.9
24.5
22.8
22.6
19.6
63.5
8.2
5.1
12.5
23.0
13.9
37.2
28.6
36.1
40.7
32.2
39.2
9.6
*Per 100,000, age adjusted to the 2000 US standard population.
Source: US Mortality Data, National Center for Health Statistics, Centers for Disease Control and Prevention.
American Cancer Society, Surveillance Research, 2014
8 Cancer Facts & Figures 2014
Selected Cancers
Breast
New cases: An estimated 232,670 new cases of invasive breast
cancer are expected to be diagnosed among women in the US
during 2014; about 2,360 new cases are expected in men. Excluding cancers of the skin, breast cancer is the most frequently
diagnosed cancer in women. The dramatic decrease in the
breast cancer incidence rate of almost 7% from 2002 to 2003 has
been attributed to reductions in the use of menopausal hormone
therapy (MHT), previously known as hormone replacement
therapy, following the publication of results from the Women’s
Health Initiative in 2002. This study found that the use of combined estrogen plus progestin MHT was associated with an
increased risk of breast cancer, as well as coronary heart disease. From 2006 to 2010, the most recent five years for which
data are available, breast cancer incidence rates were stable.
In addition to invasive breast cancer, 62,570 new cases of in situ
breast cancer are expected to occur among women in 2014. Of
these, approximately 83% will be ductal carcinoma in situ
(DCIS). In situ breast cancer incidence rates were also stable
from 2006 to 2010.
Deaths: An estimated 40,430 breast cancer deaths (40,000
women, 430 men) are expected in 2014. Breast cancer ranks second as a cause of cancer death in women (after lung cancer).
Death rates for breast cancer have steadily decreased in women
since 1989, with larger decreases in younger women; from 2006
to 2010, rates decreased 3.0% per year in women under 50 years
and 1.8% per year in women 50 and older. The decrease in breast
cancer death rates represents improvements in early detection
and treatment, and possibly decreased incidence.
Signs and symptoms: Breast cancer typically produces no
symptoms when the tumor is small and most treatable. Therefore, it is important for women to follow recommended screening
guidelines to detect breast cancer at an early stage. Larger
tumors may become evident as a breast lump, which is often
painless. Less common symptoms include persistent changes to
the breast, such as thickening, swelling, distortion, tenderness,
skin irritation, redness, scaliness, or nipple abnormalities, such
as ulceration, retraction, or spontaneous discharge. Breast pain
is more likely to be caused by benign conditions and is not a
common early symptom of breast cancer.
Risk factors: Potentially modifiable factors associated with
increased breast cancer risk include weight gain after the age of
18, being overweight or obese (for postmenopausal breast cancer), use of MHT (combined estrogen and progestin), physical
inactivity, and alcohol consumption. In addition, recent research
indicates that long-term, heavy smoking also increases breast
cancer risk, particularly among women who start smoking
before first pregnancy. The International Agency for Research
on Cancer has concluded that there is limited evidence that shift
work, particularly at night, is also associated with an increased
risk of breast cancer.
Other factors associated with increased breast cancer risk
include high breast tissue density (the amount of glandular tissue relative to fatty tissue measured on a mammogram), high
bone mineral density (women with low density are at increased
risk for osteoporosis), type 2 diabetes, certain benign breast conditions (such as atypical hyperplasia), and lobular carcinoma in
situ. High-dose radiation to the chest for cancer treatment also
increases risk. Reproductive factors that increase risk include a
long menstrual history (menstrual periods that start early and/
or end later in life), recent use of oral contraceptives or depoprovera, never having children, and having one’s first child after
age 30.
Risk is also increased by a family history of breast cancer, particularly having one or more affected first-degree relatives
(though most women with breast cancer do not have a family
history of the disease). Inherited mutations (alterations) in the
breast cancer susceptibility genes BRCA1 and BRCA2 are very
rare in the general population (much less than 1%), but account
for 5%-10% of all female breast cancers, an estimated 5%-20% of
male breast cancers, and 15%-20% of familial breast cancers.
Scientists now believe that most familial breast cancer is due to
the interaction between lifestyle factors and more common variations in the genetic code that confer a small increase in breast
cancer risk. Individuals with a strong family history of breast
and/or certain other cancers, such as ovarian and colon cancer,
should consider counseling to determine if genetic testing is
appropriate. Prevention measures may be possible for individuals with breast cancer susceptibility mutations. Studies show
that removal of the ovaries and/or breasts considerably
decreases the risk of breast cancer in BRCA1 and BRCA2 mutation carriers; however, not all women who choose this surgery
would have developed breast cancer. Women should receive
counseling before undergoing surgical procedures for breast
cancer prevention.
Factors associated with a decreased risk of breast cancer include
breastfeeding, regular moderate or vigorous physical activity,
and maintaining a healthy body weight. Two medications –
tamoxifen and raloxifene – have been approved to reduce breast
cancer risk in women at high risk. Raloxifene appears to have a
lower risk of certain side effects, such as uterine cancer and
blood clots; however, it is only approved for use in postmenopausal women.
Early detection: Breast cancer screening for women at average
risk includes clinical breast exam and mammography. Mammography can often detect breast cancer at an early stage, when
treatment is more effective. Numerous studies have shown that
Cancer Facts & Figures 2014 9
Leading New Cancer Cases and Deaths – 2014 Estimates
Estimated Deaths
Estimated New Cases*
Male
Prostate
233,000 (27%)
Lung & bronchus
116,000 (14%)
Colon & rectum
71,830 (8%)
Urinary bladder
56,390 (7%)
Melanoma of the skin
43,890 (5%)
Kidney & renal pelvis
39,140 (5%)
Non-Hodgkin lymphoma
38,270 (4%)
Oral cavity & pharynx
30,220 (4%)
Leukemia
30,100 (4%)
Liver & intrahepatic bile duct
24,600 (3%)
All sites
855,220 (100%)
Female
Breast
232,670 (29%)
Lung & bronchus
108,210 (13%)
Colon & rectum
65,000 (8%)
Uterine corpus
52,630 (6%)
Thyroid
47,790 (6%)
Non-Hodgkin lymphoma
32,530 (4%)
Melanoma of the skin
32,210 (4%)
Kidney & renal pelvis
24,780 (3%)
Pancreas
22,890 (3%)
Leukemia
22,280 (3%)
All sites
810,320 (100%)
Female
Male
Lung & bronchus
Lung & bronchus
72,330 (26%)
86,930 (28%)
Breast
Prostate
40,000 (15%)
29,480 (10%)
Colon & rectum
Colon & rectum
24,040 (9%)
26,270 (8%)
Pancreas
Pancreas
19,420 (7%)
20,170 (7%)
Ovary
Liver & intrahepatic bile duct
14,270 (5%)
15,870 (5%)
Leukemia
Leukemia
10,050 (4%)
14,040 (5%)
Uterine corpus
Esophagus
8,590 (3%)
12,450 (4%)
Non-Hodgkin lymphoma
Urinary bladder
8,520 (3%)
11,170 (4%)
Liver & intrahepatic bile duct
Non-Hodgkin lymphoma
7,130 (3%)
10,470 (3%)
Brain & other nervous system
Kidney & renal pelvis
6,230 (2%)
8,900 (3%)
All sites
All sites
275,710 (100%)
310,010 (100%)
*Excludes basal and squamous cell skin cancers and in situ carcinoma except urinary bladder.
©2014, American Cancer Society, Inc., Surveillance Research
early detection with mammography saves lives and increases
treatment options. Steady declines in breast cancer mortality
among women since 1989 have been attributed to a combination
of early detection and improvements in treatment. Mammography is a very accurate screening tool for women at both average
and increased risk; however, like any medical test, it is not perfect. Mammography will detect most breast cancers in women
without symptoms, though the sensitivity is lower for younger
women and women with dense breasts. For these women, digital
mammography or ultrasound imaging in combination with
standard mammography may increase the likelihood of detecting cancer. Mammography also results in some overdiagnoses,
which is the detection of cancer that would neither have caused
harm nor been diagnosed in the absence of screening. Most
women with an abnormal mammogram do not have cancer.
Lesions that remain suspicious after additional imaging are
usually biopsied for a definitive diagnosis. For most women at
high risk of breast cancer, annual screening using magnetic resonance imaging (MRI) in addition to mammography is
recommended, typically starting at the age of 30. (For more
information, see Breast Cancer Facts & Figures at cancer.org/statistics.) Concerted efforts should be made to improve access to
health care and encourage all women 40 and older to receive
regular mammograms. For more information on the Society’s
recommendations for breast cancer screening, see page 68.
10 Cancer Facts & Figures 2014
Treatment: Taking into account tumor size, extent of spread,
and other characteristics, as well as patient preference, treatment usually involves breast-conserving surgery (surgical
removal of the tumor and surrounding tissue) or mastectomy
(surgical removal of the breast). Numerous studies have shown
that for early breast cancer (cancer that has not spread to the
skin, chest wall, or distant organs), long-term survival is similar
among women treated with breast-conserving surgery plus
radiation therapy and those treated with mastectomy. Women
undergoing mastectomy who elect breast reconstruction have
several options, including the materials used to restore the
breast shape and the timing of the procedure.
Underarm lymph nodes are usually removed and evaluated during surgery to determine whether the tumor has spread beyond
the breast. In women with early stage disease, sentinel lymph
node biopsy, a procedure in which only the first lymph nodes to
which cancer is likely to spread are removed, has a lower chance
of long-term side effects (e.g., lymphedema, arm swelling caused
by the accumulation of lymph fluid) and is as effective as a full
axillary node dissection, in which many nodes are removed.
Treatment may also involve radiation therapy, chemotherapy
(before or after surgery), hormone therapy (e.g., selective estrogen response modifiers, aromatase inhibitors, ovarian ablation),
and/or targeted therapy. Postmenopausal women with early
stage breast cancer that tests positive for hormone receptors
benefit from treatment with an aromatase inhibitor (e.g., letrozole, anastrozole, or exemestane) in addition to, or instead of,
tamoxifen. For women whose cancer tests positive for
HER2/neu, several therapies are available that target the
growth-promoting protein HER2. The US Food and Drug
Administration (FDA) revoked approval of bevacizumab (Avastin) for the treatment of metastatic breast cancer in 2011 because
of evidence showing minimal benefit and potentially dangerous
side effects.
While some cases of ductal carcinoma in situ (DCIS) will progress to invasive cancer, many will not. However, because there
is currently no way to distinguish which lesions will go on to
cause harm, surgery is recommended for all patients. Treatment
options for DCIS include breast-conserving surgery with radiation therapy or mastectomy; if the tumor is hormone
receptor-positive, surgery may be followed by treatment with
tamoxifen. Removal of axillary lymph nodes is not generally
needed, but a sentinel lymph node procedure may be performed
with a mastectomy. A report by a panel of experts convened by
the National Institutes of Health concluded that in light of the
noninvasive nature and favorable prognosis of DCIS, the primary goal of future research should be the development of risk
categories so each patient can receive the minimum treatment
necessary for a successful outcome.
Survival: Overall, 61% of breast cancer cases are diagnosed at a
localized stage (no spread to lymph nodes or other locations outside the breast), for which the 5-year relative survival rate is 99%.
If the cancer has spread to tissues or lymph nodes under the arm
(regional stage), the survival rate is 84%. If the spread is to lymph
nodes around the collarbone or to distant lymph nodes or organs
(distant stage), the survival rate falls to 24%. For all stages combined, relative survival rates at 10 and 15 years after diagnosis
are 83% and 78%, respectively. Caution should be used when
interpreting long-term survival rates because they represent
patients who were diagnosed many years ago and do not reflect
recent advances in detection and treatment. For example,
15-year relative survival is based on patients diagnosed as early
as 1992. There are large differences in breast cancer survival by
race; for all stages combined, the 5-year survival rate is 90% for
white women and 79% for African American women.
Many studies have shown that being overweight adversely
affects survival for postmenopausal women with breast cancer.
In addition, breast cancer survivors who are more physically
active, particularly after diagnosis, are less likely to die from
breast cancer, or other causes, than those who are inactive.
For more information about breast cancer, see the American
Cancer Society’s Breast Cancer Facts & Figures, available online
at cancer.org/statistics.
Childhood Cancer (Ages 0-14 years)
See page 25 for special section on childhood and adolescent
cancers.
Colon and Rectum
New cases: An estimated 96,830 cases of colon cancer and
40,000 cases of rectal cancer are expected to be diagnosed in
2014. Colorectal cancer is the third most common cancer in both
men and women. Incidence rates have been decreasing for most
of the past two decades, which has largely been attributed to
increases in the use of colorectal cancer screening tests that
allow for the detection and removal of colorectal polyps before
they progress to cancer. From 2006 to 2010, incidence rates
declined by 3.7% per year among adults 50 years of age and older
(among whom screening is recommended), but increased by
1.8% per year among adults younger than age 50.
Deaths: An estimated 50,310 deaths from colorectal cancer are
expected to occur in 2014. Mortality rates for colorectal cancer
have declined in both men and women over the past two decades;
from 2006 to 2010, the rate declined by 2.5% per year in men and
by 3.0% per year in women. These decreases reflect declining
incidence rates and improvements in early detection and
treatment.
Signs and symptoms: Early stage colorectal cancer typically
does not have symptoms, which is why screening is usually necessary to detect this cancer in its early stages. Symptoms may
include rectal bleeding, blood in the stool, a change in bowel
habits or stool shape (e.g., narrower than usual), the feeling that
the bowel is not completely empty, cramping pain in the lower
abdomen, decreased appetite, or weight loss. In some cases,
blood loss from the cancer leads to anemia (low red blood cells),
causing symptoms such as weakness and excessive fatigue.
Timely evaluation of symptoms consistent with colorectal cancer is essential, even for adults younger than age 50, among
whom colorectal cancer is rare, but increasing.
Risk factors: The risk of colorectal cancer increases with age; in
2010, 90% of cases were diagnosed in individuals 50 years of age
and older. Modifiable factors associated with increased risk
include obesity, physical inactivity, a diet high in red or processed meat, alcohol consumption, long-term smoking, and very
low intake of fruits and vegetables. Hereditary and medical factors that increase risk include a personal or family history of
colorectal cancer and/or polyps, a personal history of chronic
inflammatory bowel disease (e.g., ulcerative colitis or Crohn disease), certain inherited genetic conditions (e.g., Lynch syndrome,
also known as hereditary non-polyposis colorectal cancer, or
familial adenomatous polyposis [FAP]), and type 2 diabetes.
Consumption of milk and calcium and higher blood levels of
vitamin D appear to decrease colorectal cancer risk. Regular use
of nonsteroidal anti-inflammatory drugs, such as aspirin, also
Cancer Facts & Figures 2014 11
reduces risk. However, these drugs are not recommended for the
prevention of colorectal cancer among individuals at average
risk because they can have serious adverse health effects. Accumulating evidence suggests that past or current use of
menopausal hormone therapy (particularly combined estrogen
and progesterone) also lowers risk. However, hormone therapy is
not recommended for the prevention of colorectal cancer
because it increases risk for breast cancer, stroke, heart attack,
and blood clots.
Early detection: Beginning at the age of 50, men and women
who are at average risk for developing colorectal cancer should
begin screening. Screening can detect and allow for the removal
of colorectal polyps that might become cancerous, as well as
detect cancer at an early stage, when treatment is usually less
extensive and more successful. In 2008, the American Cancer
Society collaborated with several other organizations to release
cancer screening guidelines. These joint guidelines emphasize
cancer prevention and draw a distinction between screening
tests that primarily detect cancer and those that can detect both
cancer and precancerous polyps. There are a number of recommended screening options, which differ by the extent of bowel
preparation, as well as test performance, limitations, time interval, and cost. For detailed information on colorectal cancer
screening options, see Colorectal Cancer Facts & Figures at cancer.org/statistics, and for the Society’s screening guidelines for
colorectal cancer, see page 68.
Treatment: Surgery is the most common treatment for colorectal cancer. For cancers that have not spread, surgical removal
may be curative. A permanent colostomy (creation of an abdominal opening for elimination of body waste) is rarely needed for
colon cancer and is infrequently required for rectal cancer. Chemotherapy alone, or in combination with radiation, is given
before (neoadjuvant) or after (adjuvant) surgery to most patients
whose cancer has penetrated the bowel wall deeply or spread to
lymph nodes. Adjuvant chemotherapy for colon cancer in otherwise healthy patients age 70 and older is equally effective as in
younger patients; toxicity in older patients can be limited by
avoiding certain drugs (e.g., oxaliplatin). Several targeted therapies have been approved by the FDA to treat metastatic colorectal
cancer.
Survival: The 1- and 5-year relative survival rates for people
with colorectal cancer are 83% and 65%, respectively. Survival
continues to decline to 58% at 10 years after diagnosis. When
colorectal cancers are detected at a localized stage, the 5-year
survival is 90%; however, only 40% of colorectal cancers are
diagnosed at this early stage, in part due to the underuse of
screening. If the cancer has spread regionally to involve nearby
organs or lymph nodes by the time of diagnosis, the 5-year survival drops to 70%. If the disease has spread to distant organs,
the 5-year survival is 13%.
12 Cancer Facts & Figures 2014
Kidney
New cases: An estimated 63,920 new cases of kidney (renal) cancer are expected to be diagnosed in 2014. This estimate largely
reflects renal cell carcinomas, which start in the body of the kidney, but also includes cancers of the renal pelvis (6%), which
behave more like bladder cancer, and Wilms tumor (1%), a childhood cancer that usually develops before the age of 5 (see special
section on childhood and adolescent cancers, page 25). After
increasing for several decades, kidney cancer incidence rates
were stable in both men and women from 2006 to 2010.
Deaths: An estimated 13,860 deaths from kidney cancer are
expected to occur in 2014. Death rates for kidney cancer
decreased by 0.9% per year from 2006 to 2010.
Signs and symptoms: Early stage kidney cancer usually has no
symptoms. As the tumor progresses, symptoms may include
blood in the urine, a pain or lump in the lower back or abdomen,
fatigue, weight loss, fever, or swelling in the legs and ankles.
Risk factors: Tobacco use is a strong risk factor for kidney cancer, with the largest risk for cancer of the renal pelvis, particularly
among heavy smokers. Additional risk factors for renal cell carcinoma include obesity, to which an estimated 30% of cases can
be attributed; high blood pressure; chronic renal failure; and
occupational exposure to certain chemicals, such as trichloroethylene, an industrial agent used as a metal degreaser and
chemical additive. Radiation exposure (such as for cancer treatment) slightly increases risk. A small proportion of renal cell
cancers are the result of rare hereditary conditions (e.g., von
Hippel-Lindau disease and hereditary papillary renal cell carcinoma). Physical activity decreases the risk of kidney cancer.
Early detection: There are no recommended screening tests for
the early detection of kidney cancer among people at average
risk.
Treatment: Active surveillance (observation) may be offered to
some patients with small tumors. Surgery (traditional or laparoscopic, i.e., minimally invasive, performed through very small
incisions) is the primary treatment for most kidney cancers.
Patients who are not surgical candidates may be offered ablation therapy, a procedure that uses heat or cold to destroy the
tumor. Kidney cancer tends to be resistant to both traditional
chemotherapy and radiation therapy. Improved understanding
of the biology of kidney cancer has led to the development of several targeted therapies that are used to treat metastatic
disease.
Survival: The 1- and 5-year relative survival rates for cancers of
the kidney are 85% and 72%, respectively. More than half (63%)
of cases are diagnosed at the local stage, for which the 5-year
relative survival rate is 92%. Five-year survival is lower for renal
pelvis (51%) than for renal cell carcinoma (73%).
Leukemia
New cases: An estimated 52,380 new cases of leukemia are
expected in 2014. Leukemia is a cancer of the bone marrow and
blood and is classified into four main groups according to cell
type and rate of growth: acute lymphocytic (ALL), chronic lymphocytic (CLL), acute myeloid (AML), and chronic myeloid
(CML). The majority (91%) of leukemia cases are diagnosed in
adults 20 years of age and older, among whom the most common
types are CLL (35%) and AML (32%). Among children and teens,
ALL is most common, accounting for 75% of leukemia cases (see
special section on childhood and adolescent cancers, page 25).
From 2006 to 2010, overall leukemia incidence rates increased
slightly (by 0.5% per year).
Deaths: An estimated 24,090 deaths are expected to occur in
2014. Death rates for leukemia have been declining for the past
several decades; from 2006 to 2010, rates decreased by 0.8% per
year among males and by 1.3% per year among females.
Signs and symptoms: Symptoms may include fatigue, paleness,
weight loss, repeated infections, fever, bruising easily, and nosebleeds or other hemorrhages. In acute leukemia, these signs can
appear suddenly. Chronic leukemia typically progresses slowly
with few symptoms and is often diagnosed during routine blood
tests. Patients with CML or CLL may experience swollen lymph
nodes or pain in the upper left abdomen due to an enlarged
spleen.
Risk factors: Exposure to ionizing radiation increases the risk
of several types of leukemia (excluding CLL). Medical radiation,
such as that used in cancer treatment, is one of the most common sources of radiation exposure. Leukemia may also occur as
a side effect of chemotherapy. Children with Down syndrome
and certain other genetic abnormalities are at increased risk of
leukemia. Workers in the rubber-manufacturing industry also
have an increased risk. Recent studies suggest that obesity
increases the risk of leukemia.
Some risk factors are most closely associated with specific types
of leukemia. For example, family history is a strong risk factor
for CLL. Cigarette smoking is a risk factor for AML in adults, and
there is accumulating evidence that parental smoking before
and after childbirth may increase the risk of childhood leukemia. There is limited evidence that maternal exposure to paint
fumes also increases the risk of childhood leukemia. Exposure
to certain chemicals, such as formaldehyde and benzene (a component in cigarette smoke and gasoline that has become more
regulated due to its carcinogenicity), increases the risk of AML.
Infection with human T-cell leukemia virus type I (HTLV-I) can
cause a rare type of leukemia called adult T-cell leukemia/lymphoma. The prevalence of HTLV-I infection is geographically
localized and is most common in southern Japan and the Caribbean; infected individuals in the US tend to be descendants or
immigrants from endemic regions.
Early detection: Although leukemia is sometimes found early
because of abnormalities on blood tests done for other indications, it is not usually diagnosed early based on symptoms
because these often resemble those of other, less serious
conditions.
Treatment: Chemotherapy is used to treat most types of leukemia. Various anticancer drugs are used, either in combination or
as single agents. Several targeted drugs (e.g., imatinib [Gleevec])
are effective for treating CML because they attack cells with the
Philadelphia chromosome, the genetic abnormality that is the
hallmark of this type of leukemia. Some of these drugs are also
FDA-approved to treat a type of ALL involving the same genetic
defect. People diagnosed with CLL that is not progressing or
causing symptoms may not require treatment. Recent clinical
trials have shown that adults with AML who are treated with
twice the conventional dose of daunorubicin experience higher
and more rapid rates of remission. Antibiotics and transfusions
of blood components are used as supportive treatments. Under
appropriate conditions, high-dose chemotherapy followed by
stem cell transplantation may be used to treat certain types of
leukemia.
Survival: Survival rates vary substantially by leukemia subtype, ranging from a current 5-year relative survival of 24% for
patients diagnosed with AML to 79% for those with CLL.
Advances in treatment have resulted in a dramatic improvement in survival over the past three decades for most types of
leukemia. For example, from 1975-1977 to 2003-2009, the overall
5-year relative survival rate for ALL increased from 41% to 69%.
In large part due to the discovery of targeted cancer drugs like
imatinib, the 5-year survival rate for CML has almost doubled
from 31% for cases diagnosed during 1990-1992 to 59% for those
diagnosed during 2003-2009.
Liver
New Cases: An estimated 33,190 new cases of liver cancer
(including intrahepatic bile duct cancers) are expected to occur
in the US during 2014. Most (80%) of these cases are hepatocellular carcinoma (HCC). Liver cancer incidence rates are about
three times higher in men than in women. From 2006 to 2010,
rates increased by 3.7% per year in men and by 2.9% per year in
women.
Deaths: An estimated 23,000 liver cancer deaths (7,130 women,
15,870 men) are expected in 2014. From 2006 to 2010, death rates
for liver cancer increased by 2.3% per year in men and 1.4% per
year in women.
Signs and symptoms: Common symptoms include abdominal
pain and/or swelling, weight loss, weakness, loss of appetite,
jaundice (a yellowish discoloration of the skin and eyes), and
fever. Enlargement of the liver is the most common physical sign.
Cancer Facts & Figures 2014 13
Probability (%) of Developing Invasive Cancers during Selected Age Intervals by Sex, US, 2008-2010*
Birth to 49 50 to 59 60 to 69 70 and Older Birth to Death
All sites Male
Female
3.5 (1 in 29)
5.4 (1 in 19)
6.8 (1 in 15)
6.0 (1 in 17)
15.4 (1 in 6)
10.1 (1 in 10)
36.9 (1 in 3)
26.7 (1 in 4)
43.9 (1 in 2)
38.0 (1 in 3)
Kidney &
renal pelvis
Male
Female
0.2 (1 in 480)
0.1 (1 in 753)
0.3 (1 in 289)
0.2 (1 in 586)
0.6 (1 in 154)
0.3 (1 in 317)
1.3 (1 in 75)
0.7 (1 in 134)
2.1 (1 in 49)
1.2 (1 in 83)
Breast
Female
1.9 (1 in 53)
2.3 (1 in 43)
3.5 (1 in 29)
6.7 (1 in 15)
12.3 (1 in 8)
Colon &
rectum
Male
Female
0.3 (1 in 305)
0.3 (1 in 334)
0.7 (1 in 144)
0.5 (1 in 189)
1.3 (1 in 76)
0.9 (1 in 109)
4.0 (1 in 25)
3.7 (1 in 27)
5.0 (1 in 20)
4.6 (1 in 22)
Leukemia
Male
Female
0.2 (1 in 421)
0.2 (1 in 526)
0.2 (1 in 614)
0.1 (1 in 979)
0.4 (1 in 279)
0.2 (1 in 475)
1.3 (1 in 76)
0.8 (1 in 120)
1.7 (1 in 60)
1.2 (1 in 86)
Lung &
bronchus
Male
Female
0.2 (1 in 548)
0.2 (1 in 522)
0.7 (1 in 134)
0.6 (1 in 171)
2.1 (1 in 47)
1.6 (1 in 62)
6.7 (1 in 15)
4.9 (1 in 20)
7.6 (1 in 13)
6.3 (1 in 16)
Melanoma
of the skin§
Male
Female
0.4 (1 in 284)
0.5 (1 in 206)
0.4 (1 in 134)
0.3 (1 in 313)
0.8 (1 in 129)
0.4 (1 in 243)
2.1 (1 in 48)
0.9 (1 in 113)
2.9 (1 in 34)
1.9 (1 in 53)
Non-Hodgkin
lymphoma
Male
Female
0.3 (1 in 357)
0.2 (1 in 537)
0.3 (1 in 338)
0.2 (1 in 475)
0.6 (1 in 171)
0.4 (1 in 233)
1.8 (1 in 56)
1.4 (1 in 71)
2.4 (1 in 42)
1.9 (1 in 52)
Prostate
Male
0.3 (1 in 298)
2.3 (1 in 43)
6.4 (1 in 16)
11.2 (1 in 9)
15.3 (1 in 7)
Uterine cervix
Female
0.3 (1 in 348)
0.1 (1 in 812)
0.1 (1 in 824)
0.2 (1 in 619)
0.7 (1 in 151)
Uterine corpus
Female
0.3 (1 in 370)
0.6 (1 in 171)
0.9 (1 in 111)
1.3 (1 in 78)
2.7 (1 in 37)
†
*For those who are cancer-free at the beginning of each age interval. †All sites excludes basal cell and squamous cell skin cancers and in situ cancers except urinary bladder. §Statistic is for whites only.
Source: DevCan: Probability of Developing or Dying of Cancer Software, Version 6.7.0. Statistical Research and Applications Branch, National Cancer Institute, 2013.
www.srab.cancer.gov/devcan.
American Cancer Society, Surveillance Research, 2014
Risk factors: In the US and other Western countries, the majority of liver cancer cases are due to alcohol-related cirrhosis, and
possibly nonalcoholic fatty liver disease associated with obesity,
diabetes, and related metabolic disorders. Chronic hepatitis B
virus (HBV) and hepatitis C virus (HCV) infections are associated with less than half of liver cancer cases in the US, although
they are the major risk factors for the disease worldwide. In the
US, rates of HCC are higher in immigrants from areas where
HBV is endemic, such as China, Southeast Asia, and sub-Saharan Africa. A vaccine that protects against HBV has been
available since 1982. Vaccination is recommended for all infants
at birth; for all children under 18 years of age who were not vaccinated at birth; and for adults in high-risk groups (e.g., health
care workers, injection drug users, and those younger than 60
years of age who have been diagnosed with diabetes). It is also
recommended that pregnant women be tested for HBV.
There is no vaccine available to prevent HCV infection, though
new antiviral therapies may prevent chronic infection among
those with acute (new) infection. The Centers for Disease Control and Prevention (CDC) recommends one-time HCV testing
for everyone born from 1945 to 1965 because people in this birth
cohort account for about three-fourths of HCV-infected individuals and HCV-related deaths in the US. Routine testing is
recommended for individuals at high risk of infection, such as
injection drug users, those on hemodialysis, and people who are
HIV infected. People who test positive can receive treatment,
14 Cancer Facts & Figures 2014
which may reduce their risk of liver cancer, and counseling to
reduce the risk of HCV transmission to others. Other preventive
measures for HCV infection include screening of donated blood,
organs, and tissues; adherence to infection control practices
during medical and dental procedures; and needle-exchange
programs for injecting drug users. For more information on viral
hepatitis, including who is at risk, visit the CDC Web site at
cdc.gov/hepatitis/.
Certain genetic disorders, such as hemochromatosis, also
increase the risk of liver cancer. In economically developing
countries, the risk is increased by some parasitic infections
(schistosomiasis and liver flukes) and consumption of food
contaminated with aflatoxin, a toxin produced by mold during
the storage of agricultural products in a warm, humid
environment.
Early detection: Screening for liver cancer has not been shown
to reduce mortality. Nonetheless, many doctors in the US screen
high-risk people (e.g., those with cirrhosis) with ultrasound or
blood tests.
Treatment: Early stage liver cancer can sometimes be successfully treated with surgery in a limited number of patients with
sufficient healthy liver tissue. Liver transplantation may be an
option for individuals with small tumors that cannot be surgically removed. Other treatment options include ablation (tumor
destruction) or embolization (blocking blood flow to the tumor).
Fewer treatment options exist for patients diagnosed at an
advanced stage. Sorafenib (Nexavar) is a targeted drug approved
for the treatment of HCC in patients who are not candidates for
surgery.
Survival: The overall 5-year relative survival rate for patients
with liver cancer is 16%. Forty-one percent of patients are diagnosed at an early stage, for which 5-year survival is 29%, up from
9% in the mid-1970s. Survival decreases to 10% and 3% for
patients who are diagnosed at regional and distant stages of disease, respectively.
Lung and Bronchus
New cases: An estimated 224,210 new cases of lung cancer are
expected in 2014, accounting for about 13% of all cancer diagnoses. The incidence rate has been declining since the mid-1980s in
men, but only since the mid-2000s in women. From 2006 to 2010,
lung cancer incidence rates decreased by 1.9% per year in men
and by 1.2% per year in women.
Deaths: Lung cancer accounts for more deaths than any other
cancer in both men and women. An estimated 159,260 deaths,
accounting for about 27% of all cancer deaths, are expected to
occur in 2014. Death rates began declining in 1991 in men and in
2003 in women. From 2006 to 2010, rates decreased 2.9% per year
in men and 1.4% per year in women. Gender differences in lung
cancer mortality reflect historical differences in patterns of
smoking uptake and cessation over the past 50 years.
Signs and symptoms: Symptoms may include persistent cough,
sputum streaked with blood, chest pain, voice change, and
recurrent pneumonia or bronchitis.
Risk factors: Cigarette smoking is by far the most important
risk factor for lung cancer; risk increases with both quantity and
duration of smoking. Cigar and pipe smoking also increase risk.
Exposure to radon gas released from soil and building materials
is estimated to be the second leading cause of lung cancer in
Europe and North America. Other risk factors include occupational or environmental exposure to secondhand smoke,
asbestos (particularly among smokers), certain metals (chromium, cadmium, arsenic), some organic chemicals, radiation,
air pollution, and diesel exhaust. Additional occupational exposures that increase risk include rubber manufacturing, paving,
roofing, painting, and chimney sweeping. Risk is also probably
increased among people with a medical history of tuberculosis.
Genetic susceptibility plays a contributing role in the development of lung cancer, especially in those who develop the disease
at a young age.
Early detection: In 2010, results from the National Lung Screening Trial (NLST) showed 20% fewer lung cancer deaths among
current and former heavy smokers who were screened with spiral CT compared to standard chest x-ray. In January 2013, the
American Cancer Society issued guidelines for the early detec-
tion of lung cancer based on a systematic review of the evidence.
These guidelines endorse a process of shared decision making
between clinicians who have access to high-volume, high-quality lung cancer screening programs and current or former adult
smokers (quit within the previous 15 years) who are 55 to 74
years of age, in good health, and with at least a 30-year pack history of smoking. Shared decision making should include a
discussion of the benefits, uncertainties, and harms associated
with lung cancer screening. For more information on lung cancer screening, see the American Cancer Society’s screening
guidelines on page 68.
Treatment: Lung cancer is classified as small cell (14%) or nonsmall cell (84%) for the purposes of treatment. Based on type and
stage of cancer, as well as specific molecular characteristics of
cancer cells, treatments include surgery, radiation therapy, chemotherapy, and targeted therapies. For early stage non-small
cell lung cancers, surgery is usually the treatment of choice; chemotherapy (sometimes in combination with radiation therapy)
is often given as well. Advanced-stage non-small cell lung cancer
patients are usually treated with chemotherapy, targeted drugs,
or some combination of the two. Chemotherapy alone or combined with radiation is the usual treatment of choice for small
cell lung cancer; on this regimen, a large percentage of patients
experience remission, though the cancer often returns.
Survival: The 1- and 5-year relative survival rates for lung cancer cases diagnosed during 2003-2009 were 43% and 17%,
respectively. Only 15% of lung cancers are diagnosed at a localized stage, for which the 5-year survival rate is 54%. The 5-year
survival for small cell lung cancer (6%) is lower than that for
non-small cell (18%).
Lymphoma
New cases: An estimated 79,990 new cases of lymphoma will be
diagnosed in 2014. Lymphoma is a type of cancer that begins in
certain immune system cells, and is classified as either Hodgkin
(9,190 cases in 2014) or non-Hodgkin (NHL, 70,800 cases in 2014).
From 2006 to 2010, incidence rates increased slightly among
men for both NHL (0.7% per year) and Hodgkin lymphoma (0.4%
per year), while among women rates were stable. However, it is
important to note that NHL encompasses a wide variety of disease subtypes for which incidence patterns may vary.
Deaths: An estimated 20,170 deaths from lymphoma will occur
in 2014, most of which are NHL (18,990). Death rates for Hodgkin
lymphoma have been decreasing for the past four decades; from
2006 to 2010, rates decreased by 2.2% per year among men and
by 2.6% per year among women. Death rates for NHL began
decreasing in the late 1990s; from 2006 to 2010, rates decreased
by 2.4% per year among men and women combined. Declines in
lymphoma death rates reflect improvements in treatment over
time.
Cancer Facts & Figures 2014 15
Signs and symptoms: The most common symptoms of lymphoma are produced by swollen lymph nodes, which can cause
lumps under the skin; chest pain and shortness of breath; and
abdominal fullness and loss of appetite. Other symptoms include
itching, night sweats, fatigue, unexplained weight loss, and
intermittent fever.
Risk factors: Like most cancers, the risk of developing NHL
increases with age. In contrast, the risk of Hodgkin lymphoma is
highest during adolescence and early adulthood. Most of the few
known risk factors for lymphoma are associated with altered
immune function. NHL risk is elevated in people who receive
immune suppressants to prevent organ transplant rejection, in
people with severe autoimmune conditions, and in people
infected with human immunodeficiency virus (HIV) or human
T-cell leukemia virus type I. Epstein Barr virus causes Burkitt
lymphoma (an aggressive type of NHL that occurs most often in
children and young adults) and is associated with a number of
autoimmune-related NHLs and some types of Hodgkin lymphoma. Chronic infection with some types of bacteria that cause
the immune system to be continuously active are associated
with certain types of NHL; for example, Helicobacter pylori (H.
pylori) infection increases the risk of gastric lymphoma and
Chlamydophila psittaci infection increases the risk of a lymphoma that occurs in the tissues of the eye. A family history of
lymphoma and a growing number of confirmed common genetic
variations are associated with modestly increased risk, including variations in the human leukocyte antigen (HLA). Working
in the rubber manufacturing industry and occupational and
environmental exposure to certain chemicals (e.g., solvents
such as dichloromethane) may also modestly increase risk.
Treatment: Non-Hodgkin lymphoma patients are usually
treated with chemotherapy; radiation, alone or in combination
with chemotherapy, is used less often. Highly specific monoclonal antibodies directed at lymphoma cells, such as rituximab
(Rituxan) and alemtuzumab (Campath), are used for some types
of NHL, as are antibodies linked to a radioactive atom, such as
ibritumomab tiuxetan (Zevalin) and tositumomab (Bexxar). If
NHL persists or recurs after standard treatment, stem cell transplantation (with high-dose or nonmyeloablative chemotherapy)
may be an option.
Hodgkin lymphoma is usually treated with chemotherapy, radiation therapy, or a combination of the two, depending on disease
stage and cell type. Stem cell transplantation may be an option
if these are not effective. The targeted drug brentuximab vedotin (Adcetris) – a monoclonal antibody linked to a chemotherapy
drug – is used to treat Hodgkin lymphoma (as well as a rare form
of NHL) in patients whose disease has failed to respond to other
treatment.
Survival: Survival varies widely by cell type and stage of disease. For NHL, the overall 1- and 5-year relative survival rates
are 81% and 69%, respectively; survival declines to 58% at 10
16 Cancer Facts & Figures 2014
years after diagnosis. For Hodgkin lymphoma, the 1-, 5-, and
10-year relative survival rates are 92%, 85%, and 80%,
respectively.
Oral Cavity and Pharynx
New cases: An estimated 42,440 new cases of cancer of the oral
cavity and pharynx (throat) are expected in 2014. Incidence
rates are more than twice as high in men as in women. From
2006 to 2010, incidence rates were stable in men and decreased
by 0.9% annually in women. However, among white men and
women, incidence rates are increasing for a subset of cancers in
the oropharynx (the middle part of the pharynx that includes
the back of the mouth, base of the tongue, and tonsils) that are
associated with human papillomavirus (HPV) infection.
Deaths: An estimated 8,390 deaths from oral cavity and pharynx cancer are expected in 2014. Death rates have been
decreasing over the past three decades; from 2006 to 2010, rates
decreased by 1.2% per year in men and by 2.1% per year in
women.
Signs and symptoms: Symptoms may include a lesion in the
throat or mouth that bleeds easily and does not heal; a persistent
red or white patch, lump or thickening in the throat or mouth;
ear pain; a neck mass; or coughing up blood. Difficulty chewing,
swallowing, or moving the tongue or jaws are often late
symptoms.
Risk factors: Known risk factors include tobacco use in any
form (smoked and smokeless) and excessive alcohol consumption. Many studies have reported a synergistic relationship
between smoking and alcohol that results in a 30-fold increased
risk for individuals who both smoke and drink heavily. HPV
infection is associated with cancers of the tonsil, base of the
tongue, and some other sites within the oropharynx and is
believed to be transmitted through sexual contact.
Early detection: Cancer can affect any part of the oral cavity,
including the lip, tongue, mouth, and throat. Visual inspection
by dentists and physicians can often detect premalignant abnormalities and cancer at an early stage, when treatment can be
both less extensive and more successful.
Treatment: Radiation therapy and surgery, separately or in
combination, are standard treatments; chemotherapy is added
for advanced disease. Targeted therapy with cetuximab
(Erbitux) may be combined with radiation in initial treatment or
used to treat recurrent cancer.
Survival: For all stages combined, about 83% of people with oral
cavity and pharynx cancer survive at least 1 year after diagnosis.
The 5-year and 10-year relative survival rates are 62% and 51%,
respectively.
Five-year Relative Survival Rates* (%) by Stage at Diagnosis, 2003-2009
Breast (female)
Colon & rectum
Esophagus
Kidney†
Larynx
Liver‡
Lung & bronchus
Melanoma of the skin
Oral cavity & pharynx
All Stages
Local
89
65
17
72
61
16
17
91
62
Regional
99
90
39
92
76
29
54
98
83
Distant
84
70
21
64
43
10
26
62
59
All Stages
Local
Regional
Distant
24
Ovary
44
92
72
13
Pancreas
6
24
9
4Prostate
99 100 100
12Stomach
28 63 28
35Testis
95 99 96
3Thyroid
98 100 97
4
Urinary bladder§78
70
33
16
Uterine cervix
68
91
57
36
Uterine corpus
82
95
68
27
2
28
4
74
55
5
16
17
*Rates are adjusted for normal life expectancy and are based on cases diagnosed in the SEER 18 areas from 2003-2009, all followed through 2010.
†Includes renal pelvis. ‡Includes intrahepatic bile duct. § Rate for in situ cases is 96%.
Local: an invasive malignant cancer confined entirely to the organ of origin. Regional: a malignant cancer that 1) has extended beyond the limits of the organ of origin
directly into surrounding organs or tissues; 2) involves regional lymph nodes; or 3) has both regional extension and involvement ­of regional lymph nodes.
Distant: a malignant cancer that has spread to parts of the body remote from the primary tumor either by direct extension or by discontinuous metastasis to distant
organs, tissues, or via the lymphatic system to distant lymph nodes.
Source: Howlader N, Noone AM, Krapcho M, et al. (eds). SEER Cancer Statistics Review, 1975-2010, National Cancer Institute, Bethesda, MD
http://seer.cancer.gov/csr/1975_2010/, based on November 2012 SEER data submission, posted to the SEER Web site, April 2013.
American Cancer Society, Surveillance Research 2014
Ovary
New cases: An estimated 21,980 new cases of ovarian cancer are
expected in the US in 2014. Incidence has been slowly decreasing
since the mid-1980s; from 2006 to 2010, the incidence rate
decreased by 0.9% per year.
Deaths: An estimated 14,270 deaths are expected in 2014. Ovarian cancer accounts for 5% of cancer deaths among women and
causes more deaths than any other cancer of the female reproductive system. From 2006 to 2010, the death rate for ovarian
cancer decreased by 2.8% per year among women younger than
65 years of age and by 1.7% per young among those 65 and older.
Signs and symptoms: Early ovarian cancer usually has no obvious symptoms. However, studies have indicated that some
women experience persistent, nonspecific symptoms, such as
bloating, pelvic or abdominal pain, difficulty eating or feeling
full quickly, or urinary urgency or frequency. Women who experience such symptoms daily for more than a few weeks should
seek prompt medical evaluation. The most common sign of
ovarian cancer is swelling of the abdomen, which is caused by
the accumulation of fluid. Abnormal vaginal bleeding is rarely a
symptom of ovarian cancer, though it is a symptom of cervical
and uterine cancers.
Risk factors: The most important risk factor is a strong family
history of breast or ovarian cancer. Women who have had breast
cancer or who have tested positive for inherited mutations in
BRCA1 or BRCA2 genes are at increased risk. Studies indicate
that preventive surgery to remove the ovaries and fallopian
tubes in these women can decrease the risk of ovarian cancer.
Other medical conditions associated with increased risk include
pelvic inflammatory disease and a genetic condition called
hereditary nonpolyposis colorectal cancer (also called Lynch
syndrome). The use of estrogen alone as menopausal hormone
therapy has been shown to increase risk in several large studies.
Tobacco smoking increases the risk of mucinous ovarian cancer.
Heavier body weight may be associated with increased risk of
ovarian cancer. Pregnancy, long-term use of oral contraceptives,
and tubal ligation reduce the risk of ovarian cancer. Hysterectomy (removal of the uterus) and salpingectomy (removal of
fallopian tubes) may decrease risk.
Early detection: There is currently no sufficiently accurate
screening test for the early detection of ovarian cancer in average risk women. Pelvic examination only occasionally detects
ovarian cancer, generally when the disease is advanced. However, for women who are at high risk, a thorough pelvic exam in
combination with transvaginal ultrasound and a blood test for
the tumor marker CA125 may be offered, though this strategy
has not yet proven effective in screening even high-risk groups of
women. Although a clinical trial in the US showed that these
tests had no effect on ovarian cancer mortality when used as a
screening tool in average risk women, results are expected in
2015 from another large screening trial under way in the United
Kingdom. A pelvic exam, sometimes in combination with a
transvaginal ultrasound, may be used to evaluate women with
symptoms.
Treatment: Treatment includes surgery and usually chemotherapy. Surgery usually involves removal of one or both ovaries
and fallopian tubes (salpingo-oophorectomy), the uterus (hysterectomy), and the omentum (fatty tissue attached to some of
the organs in the belly), along with biopsies of the peritoneum
(lining of the abdominal cavity). In younger women with very
early stage tumors who want to have children, only the involved
Cancer Facts & Figures 2014 17
Trends in 5-year Relative Survival Rates* (%) by Race, US, 1975-2009
All races
White
African American
1975-771987-89 2003-2009 1975-77 1987-89 2003-2009 1975-77 1987-89 2003-2009
All sites
49
55
Brain & other nervous system
Breast (female)
Colon
Esophagus
Hodgkin lymphoma
22
29
75
84
5160
59
72
79
68† 5057 69† 3943 61†
35†
90†
65†
19†
88†
2228
7685
5161
611
7280
33† 2532 41†
92† 6271 79†
67† 4552 56†
20† 4714†
89† 7072 83†
Kidney & renal pelvis
50
57
73† 5057 73† 4955 72†
Larynx
6666 63† 6767 64 58 56 52
Leukemia
3443 59† 3544 60† 3335 53†
Liver & intrahepatic bile duct 3
5
18† 36 17† 2312†
Lung & bronchus
12
13
18† 1213 18† 1111 14†
Melanoma of the skin
Myeloma
Non-Hodgkin lymphoma
Oral cavity & pharynx
Ovary
82
88
93†
2527 45†
47
51
71†
53
54
65†
3638 44†
8288
2427
4751
5456
3538
Pancreas
Prostate
Rectum
Stomach
Testis
24 6† 33 7† 26 6†
6883 100† 6984 100† 6171 98†
4858 68† 4859 68† 4452 62†
1520 29† 1418 28† 1619 29†
8395 97† 8396 97†73‡#88‡90
Thyroid
Urinary bladder
Uterine cervix
Uterine corpus
9294 98†
72
79
80†
69
70
69
87
82
84†
9294
7380
70
73
8884
93†57‡79‡77‡
45† 3030 44†
72† 4846 64†
67† 3634 46†
44† 4234 36
98†
81†
71
86†
9092
5063
64
57
6057
97†
64†
63
64
*Survival rates are adjusted for normal life expectancy and are based on cases diagnosed in the SEER 9 areas from 1975-77, 1987-89, and 2003 to 2009, all followed
through 2010. †The difference in rates between 1975-1977 and 2003-2009 is statistically significant (p <0.05). ‡The standard error is between 5 and 10 percentage
points. #Survival rate is for cases diagnosed in 1978-1980.
Source: Howlader N, Noone AM, Krapcho M, et al. (eds). SEER Cancer Statistics Review, 1975-2010, National Cancer Institute, Bethesda, MD
http://seer.cancer.gov/csr/1975_2010/, based on November 2012 SEER data submission, posted to the SEER Web site, April 2013.
American Cancer Society, Surveillance Research, 2014
ovary and fallopian tube may be removed. Among patients with
early ovarian cancer, complete surgical staging has been associated with better outcomes. For women with advanced disease,
surgically removing all abdominal metastases larger than one
centimeter (debulking) enhances the effect of chemotherapy
and helps improve survival. For women with stage III ovarian
cancer that has been optimally debulked, studies have shown
that chemotherapy administered both intravenously and
directly into the abdomen (intraperitoneally) improves survival.
Studies have also found that ovarian cancer patients whose surgery is performed by a gynecologic oncologist have more
successful outcomes. Clinical trials are currently under way to
test targeted drugs such as bevacizumab and cediranib in the
treatment of ovarian cancer.
Survival: Relative survival varies substantially by age; women
younger than 65 years of age are twice as likely to survive 5 years
following diagnosis as women 65 and older (57% versus 28%).
Overall, the 1-, 5-, and 10-year relative survival rates for ovarian
cancer patients are 75%, 44%, and 35%, respectively. If diagnosed
at the localized stage, the 5-year survival rate is 92%; however,
18 Cancer Facts & Figures 2014
only 15% of all cases are detected at this stage, usually incidentally during another medical procedure. The majority of cases
(61%) are diagnosed at distant stage, for which the 5-year survival rate is 27%.
Pancreas
New cases: An estimated 46,420 new cases of pancreatic cancer
are expected to occur in the US in 2014. Pancreatic cancer incidence rates have been increasing at about the same rate among
men and women since around 2000; from 2006 to 2010, rates
increased by 1.3% per year.
Deaths: An estimated 39,590 deaths are expected to occur in
2014, about the same number in women (19,420) as in men
(20,170). From 2006 to 2010, the death rate for pancreatic cancer
increased by 0.4% per year.
Signs and symptoms: Cancer of the pancreas usually develops
without early symptoms. Symptoms may include weight loss,
mild abdominal discomfort that may radiate to the back, and
occasionally glucose intolerance (high blood glucose levels).
Tumors that develop near the common bile duct may cause a
blockage that leads to jaundice (yellowing of the skin and eyes),
which can sometimes allow the tumor to be diagnosed at an
early stage. Signs of advanced stage disease may include severe
abdominal pain, nausea, and vomiting.
Risk factors: Approximately 20% of pancreatic cancers are
attributable to cigarette smoking; incidence rates are about
twice as high for smokers as for never smokers. Use of smokeless
tobacco products also increases risk. Aside from tobacco, risk
increases with a family history of pancreatic cancer and a personal history of chronic pancreatitis, diabetes, obesity, and
possibly high levels of alcohol consumption. Individuals with
Lynch syndrome and certain other genetic syndromes are also
at increased risk. Studies suggest that chronic infection with
HBV, HCV, or H. pylori may also increase risk. Though evidence
is still accumulating, consumption of red or processed meat, or
meat cooked at very high temperatures, may slightly increase
risk.
Early detection: At present, there is no reliable method for the
early detection of pancreatic cancer, though research is under
way in this area.
Treatment: Surgery, radiation therapy, and chemotherapy are
treatment options that may extend survival and/or relieve
symptoms in many patients, but they seldom produce a cure.
Less than 20% of patients are candidates for surgery because
pancreatic cancer is usually detected after it has spread beyond
the pancreas. Even among those patients who were thought to
be surgical candidates, the cancer has often spread too extensively to be removed. For those who do undergo surgery, adjuvant
treatment with the chemotherapy drug gemcitabine lengthens
survival. For advanced disease, chemotherapy is often offered
and may lengthen survival. The targeted anticancer drug erlotinib (Tarceva) has demonstrated a slight improvement in
advanced pancreatic cancer survival when used in combination
with gemcitabine. Clinical trials with several new agents, combined with radiation and surgery, may offer improved survival.
Survival: For all stages combined, the 1- and 5-year relative survival rates are 27% and 6%, respectively. Even for the small
percentage of people diagnosed with local disease (9%), the
5-year survival is only 24%. More than half (53%) of patients are
diagnosed at a distant stage, for which 5-year survival is 2%.
Prostate
New cases: An estimated 233,000 new cases of prostate cancer
will occur in the US during 2014. Prostate cancer is the most frequently diagnosed cancer in men aside from skin cancer. For
reasons that remain unclear, incidence rates are about 60%
higher in African Americans than in non-Hispanic whites. Incidence rates for prostate cancer changed substantially between
the mid-1980s and mid-1990s and have since fluctuated widely
from year to year, in large part reflecting changes in the use of
the prostate-specific antigen (PSA) blood test for screening.
From 2006 to 2010, incidence rates decreased by 2.0% per year.
Deaths: With an estimated 29,480 deaths in 2014, prostate cancer is the second-leading cause of cancer death in men. Prostate
cancer death rates have been decreasing since the early 1990s in
men of all races/ethnicities, though they remain more than
twice as high in African Americans as in any other group (see
table in the Cancer Disparities section on page 51). Overall, prostate cancer death rates decreased by 3.1% per year from 2006 to
2010.
Signs and symptoms: Early prostate cancer usually has no
symptoms. With more advanced disease, men may experience
weak or interrupted urine flow; the inability to urinate or difficulty starting or stopping the urine flow; the need to urinate
frequently, especially at night; blood in the urine; or pain or
burning with urination. Advanced prostate cancer commonly
spreads to the bones, which can cause pain in the hips, spine,
ribs, or other areas.
Risk factors: The only well-established risk factors for prostate
cancer are increasing age, African ancestry, a family history of
the disease, and certain inherited genetic conditions. About 60%
of all prostate cancer cases are diagnosed in men 65 years of age
and older, and 97% occur in men 50 and older. African American
men and Caribbean men of African descent have the highest
documented prostate cancer incidence rates in the world.
Genetic studies suggest that strong familial predisposition may
be responsible for 5%-10% of prostate cancers. Inherited conditions associated with increased risk include Lynch syndrome
and the BRCA2 mutation phenotype. Studies suggest that a diet
high in processed meat or dairy foods may be a risk factor, and
obesity appears to increase the risk of aggressive prostate cancer. There is some evidence that occupational exposures of
firefighters (e.g., toxic combustion products) increase risk.
Prevention: The chemoprevention of prostate cancer is an
active area of research. Two drugs of interest, finasteride and
dutasteride, reduce the amount of certain male hormones in the
body and are approved to treat the symptoms of benign prostate
enlargement. Both drugs have been found to lower the risk of
prostate cancer by 25% in large clinical trials with similar potential side effects, including reduced libido and the risk of erectile
dysfunction. However, a study of long-term survival among participants in the finasteride trial recently reported that the drug
had no effect on overall survival or survival after the diagnosis
of prostate cancer. Neither finasteride nor dutasteride is
approved for the prevention of prostate cancer at this time.
Early detection: Results from two large clinical trials designed
to determine the efficacy of PSA testing for reducing prostate
Cancer Facts & Figures 2014 19
cancer death were inconsistent. Given the significant potential
for serious side effects associated with prostate cancer treatment, along with concerns about the high prevalence of
slow-growing, non-lethal disease, no organizations presently
endorse regular prostate cancer screening. The American Cancer Society recommends that beginning at the age of 50, men
who are at average risk of prostate cancer and have a life expectancy of at least 10 years have a conversation with their health
care provider about the benefits and limitations of PSA testing.
Men should have an opportunity to make an informed decision
about whether to be tested based on their personal values and
preferences. Men at high risk of developing prostate cancer
(African Americans or men with a close relative diagnosed with
prostate cancer before the age of 65) should have this discussion
with their health care provider beginning at 45. Men at even
higher risk (because they have several close relatives diagnosed
with prostate cancer at an early age) should have this discussion
with their provider at 40. The American Urologic Association
recently issued similar recommendations. Current research is
exploring new biologic markers for prostate cancer to improve
diagnosis and prognosis.
Treatment: Treatment options vary depending on age, stage,
and grade of cancer, as well as other medical conditions. The
grade assigned to the tumor, typically called the Gleason score,
indicates the likely aggressiveness of the cancer. Although
scores as low as 2 are theoretically possible, in practice most
cancers are assigned scores ranging from 6 (low grade, less
aggressive) to 10 (high grade, very aggressive).
Early stage disease may be treated with surgery (open, laparoscopic, or robotic-assisted), external beam radiation, or
radioactive seed implants (brachytherapy). Data show similar
survival rates for patients with early stage disease treated with
any of these methods, and there is no current evidence supporting a “best” treatment for prostate cancer. Hormonal therapy
may be used along with surgery or radiation therapy in some
cases. Treatment often impacts a man’s quality of life due to side
effects or complications, such as urinary and erectile difficulties, that may be short or long term. Accumulating evidence
indicates that careful observation (“active surveillance”), rather
than immediate treatment, can be an appropriate option for
men with less aggressive tumors and for older men.
More advanced disease is treated with hormonal therapy, chemotherapy, radiation therapy, and/or other treatments.
Hormone treatment may control advanced prostate cancer for
long periods by shrinking the size or limiting the growth of the
cancer, thus helping to relieve pain and other symptoms. An
option for some men with advanced prostate cancer that is no
longer responding to hormones is a cancer vaccine known as
sipuleucel-T (Provenge). For this treatment, special immune
cells are removed from a man’s body, exposed to prostate proteins in a lab, and then re-infused back into the body, where they
20 Cancer Facts & Figures 2014
attack prostate cancer cells. Newer, more effective forms of hormone therapy, such as abiraterone (Zytiga) and enzalutamide
(Xtandi), have been shown to be beneficial for the treatment of
metastatic disease that is resistant to initial hormone therapy
and/or chemotherapy. Radium-223 (Xofigo) was recently
approved to treat hormone-resistant prostate cancer that has
spread to the bones.
Survival: The majority (93%) of prostate cancers are discovered
in the local or regional stages, for which the 5-year relative survival rate approaches 100%. Over the past 25 years, the 5-year
relative survival rate for all stages combined has increased from
68% to almost 100%. According to the most recent data, 10- and
15-year relative survival rates are 99% and 94%, respectively.
Obesity and smoking are associated with an increased risk of
dying from prostate cancer.
Skin
New cases: The number of basal cell and squamous cell skin
cancers (i.e., keratinocyte carcinomas), more commonly referred
to as nonmelanoma skin cancers (NMSC), is difficult to estimate
because these cases are not required to be reported to cancer
registries. One study of NMSC occurrence in the US estimated
that in 2006, 3.5 million cases were diagnosed among 2.2 million
people. Most cases of NMSC are highly curable.
An estimated 76,100 new cases of melanoma will be diagnosed
in 2014. Melanoma accounts for less than 2% of all skin cancer
cases, but the vast majority of skin cancer deaths. Melanoma is
rare among African Americans; lifetime risk of developing the
disease is 0.1%, compared to 2.4% among whites. Incidence rates
are higher in women than in men before the age of 45, but by the
age of 60, rates in men are more than double those in women and
by the age of 80 they are almost triple. Melanoma incidence rates
have been increasing for at least 30 years. From 2006 to 2010,
incidence rates among whites increased by 2.7% per year.
Deaths: An estimated 9,710 deaths from melanoma and 3,270
deaths from other types of skin cancer (not including NMSC)
will occur in 2014. Death rates for melanoma have been declining rapidly in whites younger than 50: from 2006 to 2010, rates
decreased by 2.6% per year in men and by 2.0% per year in
women. In contrast, among whites 50 and older, death rates
increased by 1.1% per year in men and by 0.2% per year in women
during this same time period.
Signs and symptoms: Important warning signs of melanoma
include changes in the size, shape, or color of a mole or other skin
lesion, the appearance of a new growth on the skin, or a sore that
doesn’t heal. Changes that progress over a month or more should
be evaluated by a doctor. Basal cell carcinomas may appear as
growths that are flat, or as small, raised, pink or red, translucent, shiny areas that may bleed following minor injury.
Squamous cell carcinomas may appear as growing lumps, often
with a rough surface, or as flat, reddish patches that grow slowly.
Risk factors: Risk factors vary for different types of skin cancer.
For melanoma, major risk factors include a personal or family
history of melanoma and the presence of atypical, large, or
numerous (more than 50) moles. Other risk factors for all types
of skin cancer include sun sensitivity (e.g., sunburning easily,
difficulty tanning, or natural blond or red hair color); a history of
excessive sun exposure, including sunburns; use of tanning
booths; diseases or treatments that suppress the immune system; and a past history of skin cancer.
Prevention: Skin should be protected from intense sun exposure by wearing tightly woven clothing and a wide-brimmed
hat, applying sunscreen that has a sun protection factor (SPF) of
30 or higher to unprotected skin, seeking shade (especially at
midday, when the sun’s rays are strongest), and avoiding sunbathing and indoor tanning. Sunglasses should be worn to
protect the skin around the eyes. Children in particular should
be protected from the sun because severe sunburns in childhood may greatly increase the risk of melanoma later in life.
Tanning beds and sun lamps, which provide an additional
source of UV radiation, can cause skin cancer and should be
avoided. The International Agency for Research on Cancer has
classified indoor tanning devices as “carcinogenic to humans”
based on an extensive review of scientific evidence.
Early detection: At this time, the best way to detect skin cancer
early is to recognize new or changing skin growths, particularly
those that look different than surrounding moles. All major
areas of the skin should be examined regularly, and any new or
unusual lesions, or a progressive change in a lesion’s appearance
(size, shape, or color, etc.), should be evaluated promptly by a
physician. Melanomas often start as small, mole-like growths
that increase in size and may change color. A simple ABCD rule
outlines the warning signals of the most common type of melanoma: A is for asymmetry (one half of the mole does not match
the other half); B is for border irregularity (the edges are ragged,
notched, or blurred); C is for color (the pigmentation is not uniform, with variable degrees of tan, brown, or black); D is for
diameter greater than 6 millimeters (about the size of a pencil
eraser). Other types of melanoma may not have these signs, so be
alert for any new or changing skin growths.
Treatment: Most early skin cancers are diagnosed and treated
by removal and microscopic examination of the cells. Early stage
basal cell and squamous cell cancers can be treated in most
cases by one of several methods: surgical excision, electrodesiccation and curettage (tissue destruction by electric current and
removal by scraping with a curette), or cryosurgery (tissue
destruction by freezing). Radiation therapy and certain topical
medications may be used in some cases. For malignant melanoma, the primary growth and surrounding normal tissue are
removed and sometimes a sentinel lymph node is biopsied to
determine stage. More extensive lymph node surgery may be
needed if the sentinel lymph nodes contain cancer. Melanomas
with deep invasion or that have spread to lymph nodes may be
treated with surgery, immunotherapy, chemotherapy, and/or
radiation therapy. Advanced cases of melanoma are treated
with palliative surgery, newer targeted or immunotherapy
drugs, and sometimes chemotherapy and/or radiation therapy.
The treatment of advanced melanoma has changed in recent
years with the FDA approval of targeted drugs such as vemurafenib (Zelboraf), dabrafenib (Tafinlar), and trametinib
(Mekinist) and the immunotherapy drug ipilimumab (Yervoy).
Survival: Almost all cases of basal cell and squamous cell skin
cancer can be cured, especially if the cancer is detected and
treated early. Melanoma is also highly curable if detected in its
earliest stages and treated properly. However, melanoma is more
likely than NMSCs to spread to other parts of the body. The 5and 10-year relative survival rates for people with melanoma are
91% and 89%, respectively. For localized melanoma (84% of
cases), the 5-year survival rate is 98%; survival declines to 62%
and 16% for regional and distant stage disease, respectively.
Thyroid
New cases: An estimated 62,980 new cases of thyroid cancer are
expected to be diagnosed in 2014 in the US, with 3 in 4 cases
occurring in women. Thyroid cancer is the most rapidly increasing cancer in the US and has been increasing worldwide over the
past few decades. The rise is thought to be partly due to increased
detection because of more sensitive diagnostic procedures, perhaps resulting in some overdiagnoses. In the US, rates increased
by 5.4% per year in men and by 6.5% per year in women from
2006 to 2010.
Deaths: An estimated 1,890 deaths from thyroid cancer are
expected in 2014 in the US. From 2006 to 2010, the death rate for
thyroid cancer was stable at 0.5 per 100,000 in both men and
women.
Signs and symptoms: The most common symptom of thyroid
cancer is a lump in the neck that is noticed by a patient or felt by
a health care provider during a clinical exam. Other symptoms
include a tight or full feeling in the neck, difficulty breathing or
swallowing, hoarseness, swollen lymph nodes, and pain in the
throat or neck that does not go away. Although most lumps in
the thyroid gland are not cancerous, individuals who notice an
abnormality should seek timely medical attention. Many thyroid cancers are diagnosed in people without symptoms because
an abnormality is seen on a CT scan or other imaging test performed for another purpose.
Risk factors: Risk factors for thyroid cancer include being
female, having a history of goiter (enlarged thyroid) or thyroid
nodules, a family history of thyroid cancer, and radiation exposure early in life (e.g., as a result of medical treatment). Certain
Cancer Facts & Figures 2014 21
rare genetic syndromes also increase risk. People who test positive for an abnormal gene that causes a hereditary form of
thyroid cancer can decrease the risk of developing the disease
with surgical removal of the thyroid gland. Unlike most other
adult cancers, for which older age increases risk, 80% of newly
diagnosed thyroid cancers are in patients younger than age 65.
Early detection: At present, there is no screening test recommended for the early detection of thyroid cancer. However,
because symptoms usually develop early and many cancers are
found incidentally, most thyroid cancers (68%) are diagnosed at
an early stage. Tests used in the diagnosis of thyroid cancer
include blood tests to determine thyroid hormone levels, medical imaging, and biopsy.
Treatment: Most thyroid cancers are highly curable, though
about 5% of cases (medullary and anaplastic thyroid cancers)
are more aggressive and more likely to spread to other organs.
Treatment depends on the cell type, tumor size, and extent of
the disease. The first choice of treatment is usually surgery,
involving total or partial removal of the thyroid gland (thyroidectomy), with or without lymph node removal. Treatment with
radioactive iodine (I-131) after surgery to destroy any remaining
thyroid tissue may be recommended for more advanced disease.
Hormone therapy is given after thyroidectomy to replace hormones normally produced by the thyroid gland and to prevent
the body from making thyroid-stimulating hormone, decreasing
the likelihood of recurrence.
Survival: The overall 5-year relative survival rate is 98%. However, survival varies by stage, age at diagnosis, and disease
subtype. The 5-year survival rate approaches 100% for localized
disease, is 97% for regional stage disease, and 55% for distant
stage disease.
Urinary Bladder
New cases: An estimated 74,690 new cases of bladder cancer are
expected to occur in 2014. From 2006 to 2010, bladder cancer
incidence rates were stable in men and decreased by 0.4% per
year in women. Bladder cancer incidence is about four times
higher in men than in women and almost two times higher in
white men than in African American men.
Deaths: An estimated 15,580 deaths will occur in 2014. From
2006 to 2010, death rates were stable in men and decreased by
0.5% per year in women.
Signs and symptoms: The most common symptom is blood in
the urine. Other symptoms include increased frequency or
urgency of urination and pain or feelings of irritation during
urination.
Risk factors: Smoking is the most well-established risk factor
for bladder cancer. The risk of bladder cancer among smokers is
approximately four-fold that among nonsmokers. Half of all
22 Cancer Facts & Figures 2014
bladder cancers in both men and women are attributed to smoking. Workers in the dye, rubber, leather, and aluminum
industries, painters, people who live in communities with high
levels of arsenic in the drinking water, and people with certain
bladder birth defects also have an increased risk.
Early detection: There is currently no screening method recommended for people at average risk. Bladder cancer is
diagnosed by microscopic examination of cells from urine or
bladder tissue and examination of the bladder wall with a cystoscope, a slender tube fitted with a lens and light that can be
inserted through the urethra. These and other tests may be used
to screen people at increased risk, as well as during follow up
after bladder cancer treatment to detect recurrent or new
tumors.
Treatment: Surgery, alone or in combination with other treatments, is used in more than 90% of cases. Early stage cancers
may be treated by removing the tumor and then administering
immunotherapy or chemotherapy drugs directly into the bladder after surgery. More advanced cancers may require removal
of the entire bladder (cystectomy). Patient outcomes are
improved with the use of chemotherapy, alone or with radiation,
before cystectomy. Timely follow-up care is extremely important
because of the high rate of bladder cancer recurrence.
Survival: For all stages combined, the 5-year relative survival
rate is 78%. Survival declines to 71% at 10 years and 66% at 15
years after diagnosis. Half of all bladder cancer patients are
diagnosed while the tumor is in situ (noninvasive, present only
in the layer of cells in which the cancer developed), for which the
5-year survival is 96%. Patients with invasive tumors diagnosed
at a localized stage have a 5-year survival rate of 70%; 35% of
cancers are detected at this early stage. For patients diagnosed
with regional and distant stage disease, 5-year survival is 33%
and 5%, respectively.
Uterine Cervix
New cases: An estimated 12,360 cases of invasive cervical cancer are expected to be diagnosed in 2014. Large declines in
incidence rates over most of the past several decades have begun
to taper off, particularly among younger women; from 2006 to
2010, rates were stable in women younger than 50 years of age
and decreasing by 3.1% per year in women 50 and older.
Deaths: An estimated 4,020 deaths from cervical cancer are
expected in 2014. Mortality rates declined rapidly in past
decades due to prevention and early detection as a result of
screening with the Pap test; however, similar to incidence, mortality rates have begun to level off in recent years, particularly
among younger women. From 2006 to 2010, death rates were
stable among women younger than 50, but continued to decrease
among those 50 years of age and older (by 1.2% per year).
Signs and symptoms: Pre-invasive cervical lesions often have
no symptoms. Once abnormal cervical cells become cancerous
and invade nearby tissue, the most common symptom is abnormal vaginal bleeding. Bleeding may start and stop between
regular menstrual periods, or it may occur after sexual intercourse, douching, or a pelvic exam. Menstrual bleeding may last
longer and be heavier than usual. Bleeding after menopause or
increased vaginal discharge may also be symptoms.
Risk factors: Most cervical cancers are caused by persistent
infection with certain types of human papillomavirus (HPV).
While women who begin having sex at an early age or who have
had many sexual partners are at increased risk for HPV infection and cervical cancer, a woman may be infected with HPV
even if she has had only one sexual partner. In fact, HPV infections are common in healthy women and are usually cleared
successfully by the immune system. Only rarely does the infection persist, increasing the risk of cervical cancer. Both the
persistence of HPV infection and the progression to cancer may
be influenced by many factors, including a suppressed immune
system, a high number of live childbirths, and cigarette smoking. Long-term use of oral contraceptives (birth control pills) is
also associated with increased risk of cervical cancer.
Prevention: There are two vaccines (Gardasil and Cervarix)
recommended for use in females 9 to 26 years of age for protection against the two types of HPV that cause most (70%) cervical
cancers. HPV vaccines cannot protect against established infections, nor do they protect against all types of HPV that cause
cervical cancer, which is why vaccinated women should still be
screened for cervical cancer.
Screening can prevent cervical cancer by detecting precancerous lesions. As screening has become more common,
precancerous lesions of the cervix are detected far more frequently than invasive cancer. The Pap test is the most widely
used cervical cancer screening method. It is a simple procedure
in which a small sample of cells is collected from the cervix and
examined under a microscope. Pap tests are effective, but not
perfect. Sometimes results are reported as normal when abnormal cells are present (false negative), and likewise, sometimes
test results are positive when no cancer or precancer is present
(false positive). HPV tests, which detect HPV infections associated with cervical cancer, can forecast cervical cancer risk many
years in the future and are used in conjunction with the Pap test,
either as an additional screening test or when Pap test results
are uncertain. Most cervical precancers develop slowly, so cancer can usually be prevented if a woman is screened regularly. It
is important for all women, even those who have received the
HPV vaccine, to follow cervical cancer screening guidelines.
Early detection: In addition to preventing cervical cancer,
screening can detect invasive cancer early, when treatment is
most successful. Most cervical cancers are detected in women
who have never or have not recently been screened. The Ameri-
can Cancer Society, in collaboration with the American Society
for Colposcopy and Cervical Pathology and the American Society for Clinical Pathology, issued new screening guidelines for
the prevention and early detection of cervical cancer in 2012.
The most important changes to the guidelines are the age range
for which screening is appropriate and the emphasis on the
incorporation of HPV testing in addition to the Pap test. Among
women at average risk, screening is now recommended for those
21 to 65 years of age, and the preferred screening method for
women 30 to 65 is now HPV and Pap “co-testing” every five years.
For more detailed information on the American Cancer Society’s
screening guidelines for the early detection of cervical cancer,
see page 68.
Treatment: Precancerous cervical lesions may be treated with a
loop electrosurgical excision procedure (LEEP), which removes
abnormal tissue with a wire loop heated by electric current;
cryotherapy (the destruction of cells by extreme cold); laser ablation (removal of tissue); or local surgery. Invasive cervical
cancers are generally treated with surgery or with radiation
combined with chemotherapy. Chemotherapy alone is often
used to treat advanced disease.
Survival: One- and 5-year relative survival rates for cervical
cancer patients are 87% and 68%, respectively. The 5-year survival rate for patients diagnosed with localized, regional, and
distant disease is 91%, 57%, and 16%, respectively. Cervical cancer is diagnosed at a localized stage more often in whites (49%)
than in African Americans (39%) and more often in women
younger than 50 years of age (59%) than in women 50 and older
(33%).
Uterine Corpus (Endometrium)
New cases: An estimated 52,630 cases of cancer of the uterine
corpus (body of the uterus) are expected to be diagnosed in 2014.
These usually occur in the endometrium (lining of the uterus).
From 2006 to 2010, incidence rates of endometrial cancer
increased by 1.5% per year among women younger than 50 years
and by 2.6% per year among women 50 and older.
Deaths: An estimated 8,590 deaths are expected in 2014. From
2006 to 2010, death rates for cancer of the uterine corpus
increased by 1.5% per year among women younger than 50 and
were stable among women 50 and older.
Signs and symptoms: Abnormal uterine bleeding or spotting
(especially in postmenopausal women) is a frequent early sign.
Pain during urination, intercourse, or in the pelvic area is also
a symptom.
Risk factors: Obesity and abdominal fatness increase the risk of
endometrial cancer, most likely by increasing the amount of
estrogen in the body. Estrogen exposure is a strong risk factor for
endometrial cancer. Other factors that increase estrogen exposure include menopausal estrogen therapy, late menopause,
Cancer Facts & Figures 2014 23
never having children, and a history of polycystic ovary syndrome. (Estrogen plus progestin menopausal hormone therapy
does not appear to increase risk.) Tamoxifen, a drug used to
reduce breast cancer risk, increases risk slightly because it has
estrogen-like effects on the uterus. Medical conditions that
increase risk include Lynch syndrome (also known as hereditary
nonpolyposis colorectal cancer) and diabetes. Pregnancy, use of
oral contraceptives or intrauterine devices, and physical activity
are associated with reduced endometrial cancer risk.
Early detection: There is no standard or routine screening test
for endometrial cancer. Most endometrial cancer (68%) is diagnosed at an early stage because of postmenopausal bleeding.
Women are encouraged to report any unexpected bleeding or
spotting to their physicians. The American Cancer Society rec-
24 Cancer Facts & Figures 2014
ommends that women with known or suspected Lynch
syndrome be offered annual screening with endometrial biopsy
and/or transvaginal ultrasound beginning at 35 years of age.
Treatment: Uterine corpus cancers are usually treated with
surgery, radiation, hormones, and/or chemotherapy, depending
on the stage of disease.
Survival: The 1- and 5-year relative survival rates for uterine
corpus cancer are 92% and 82%, respectively. The 5-year survival
rate is 95%, 68%, or 17%, if the cancer is diagnosed at a local,
regional, or distant stage, respectively. The overall 5-year relative survival for whites (84%) is 23 percentage points higher than
that for African Americans (61%). Higher body weight adversely
affects endometrial cancer survival, whereas physical activity is
associated with improved survival.
Special Section:
Cancer in Children & Adolescents
Overview
The news of a cancer diagnosis is never welcome, but may be
even more unexpected and difficult when the disease is diagnosed in a child or adolescent. Although cancer is much less
common among children compared to older adults, approximately 1 in 285 children in the US will be diagnosed with the
disease before the age of 20. While advances in treatment have
increased the survival rate for many childhood cancers, the disease is still the second leading cause of death (following
accidents) in children ages 5-14.1
The types of cancers that develop in children and adolescents
differ from those that develop in adults. The predominant types
of pediatric cancers (ages 0-19) are leukemia (26%), cancers of
the brain and central nervous system (CNS) (18%), and lymphoma (14%). Some of the cancers that develop in children are
rarely seen in older individuals, notably those cancers that arise
from embryonic cells and originate in developing tissues and
organ systems. Embryonal cancers include neuroblastoma
(sympathetic peripheral nervous system), Wilms tumor or
nephroblastoma (developing kidney), medulloblastomas (brain),
rhabdomyosarcomas (muscle), and retinoblastoma (retina of the
eye). Some pediatric cancers, particularly those that are more
common in adolescents, are more similar to those that arise in
adults (e.g., acute myeloid leukemia, Hodgkin lymphoma, thyroid cancer, and melanoma).
Pediatric cancers represent 1% of all new cancers diagnosed in
the US. Because these cancers occur in the context of rapid
growth and development, most experts strongly recommend
that they be treated at medical centers specialized in childhood
cancer by multidisciplinary teams including pediatric oncologists, surgeons, radiation oncologists, and other specialists. At
pediatric cancer centers, treatment protocols are available for
most types of cancer that occur in children and adolescents, and
the opportunity to participate in clinical trials is offered to most
patients and their families. Clinical trials are generally designed
to compare a potential improvement in therapy with therapy
that is currently accepted as standard; improvements may result
in an increase in cure rates or a reduction in acute or long-term
complications. Member institutions of the Children’s Oncology
Group (COG), a National Cancer Institute-supported clinical trials group, care for more than 90% of US children and adolescents
diagnosed with cancer (childrensoncologygroup.org). The COG
has nearly 100 active clinical trials open at any given time, which
include studies to test the efficacy of new treatments for many
types of childhood cancers at diagnosis or recurrent diseases,
improve understanding of the underlying biology of these diseases, and improve supportive care and survivorship. Children
and adolescents diagnosed with types of cancer more commonly
seen in adults also benefit from treatment in pediatric cancer
centers.
In this special section, we provide an overview of trends in incidence, mortality, and survival for cancers commonly diagnosed
in children and adolescents. We also provide more detailed
information on risk factors, symptoms, treatment, and important long-term and late effects for these cancers. The major
types of cancers included are: leukemias and lymphomas, brain
and CNS tumors, embryonal tumors, sarcomas of bone and soft
tissue, and gonadal germ cell tumors.
How Many Cases and Deaths Are Expected to
Occur in 2014?
An estimated 10,450 new cases and 1,350 cancer deaths are
expected to occur among children (ages 0-14) in 2014. The corresponding figures among adolescents (ages 15-19) are 5,330
new cases and 610 cancer deaths.
What Are the Most Common Cancers in
Children and Adolescents?
The most common cancers among children and adolescents
vary by age and are shown in Figure 1 (page 26).
• Cancers that are most common in children ages 0-14 are
acute lymphocytic leukemia (26%), brain and CNS (21%), neuroblastoma (7%), and non-Hodgkin lymphoma (6%).
• The most common cancers among adolescents ages 15-19 are
Hodgkin lymphoma (15%), thyroid carcinoma (11%), brain
and CNS (10%), and testicular germ cell tumors (8%).
While cancers occurring in adults are classified by the anatomical site of the primary tumor, cancers in children and younger adolescents are classified by histology (tissue type) into 12 major groups using the International Classification of Childhood Cancers (ICCC).2
Figure 1 (page 26) shows the distribution of the most common cancers in children and adolescents by ICCC group.
Cancer Facts & Figures 2014 25
Figure 1. Estimated Cases for Childhood and Adolescent Cancers, US, 2014
Children (Ages 0-14)
Adolescents (Ages 15-19)
Acute lymphocytic leukemia
2,670 (26%)
Brain and CNS
2,240 (21%)
Neuroblastoma*
710 (7%)
Non-Hodgkin lymphoma
620 (6%)
Wilms tumor
510 (5%)
Acute myeloid leukemia
500 (5%)
Bone tumors†
450 (4%)
Hodgkin lymphoma
380 (4%)
Rhabdomyosarcoma
340 (3%)
Retinoblastoma
280 (3%)
All sites
10,450
Hodgkin lymphoma
800 (15%)
Thyroid carcinoma
570 (11%)
Brain and CNS
540 (10%)
Testicular germ cell tumors
430 (8%)
Non-Hodgkin lymphoma
420 (8%)
Acute lymphocytic leukemia
410 (8%)
Bone tumors†
370 (7%)
Melanoma
310 (6%)
Acute myeloid leukemia
230 (4%)
Ovarian germ cell tumors
110 (2%)
All sites
5,330
Estimates are for malignant cancers only and are rounded to the nearest 10. In addition, 730 children and 630 adolescents will be diagnosed with benign and borderline brain tumors in 2014.
CNS = central nervous system
* Includes ganglioneuroblastoma.
©2014, American Cancer Society, Inc.
†Bone tumors include osteosarcoma and Ewing sarcoma.
How Do Childhood and Adolescent Cancers
Vary in the US Population?
Table 1 (page 28) summarizes differences in cancer incidence,
mortality, and survival rates by sex and race/ethnicity.
Sex
• In children, incidence and mortality rates are lower in girls
than in boys, while survival rates are similar.
• In adolescents, boys and girls have similar incidence rates,
while mortality rates are lower and survival is higher for
girls. Some of these differences may reflect the different types
of cancers that occur in boys compared to girls in this age
group.
Race/Ethnicity
Cancer incidence, mortality, and survival rates show substantial
variability by race and ethnicity.
• Non-Hispanic white (white) and Hispanic children have the
highest incidence rates for childhood and adolescent cancers.
• Although incidence rates are substantially lower for nonHispanic black (African American) children and adolescents
than for whites and Hispanics, death rates are similar due to
lower survival rates in African Americans.
26 Cancer Facts & Figures 2014
• Incidence and mortality rates for Asian American/Pacific
Islander children are lower than those for whites and generally similar to rates in African American children.
• American Indian/Alaska Native children have the lowest cancer incidence and mortality of all racial/ethnic groups.
Reasons for differences in incidence rates of childhood cancers
by race and ethnicity in the US are not well understood. Unlike
many adult cancers, incidence is not consistently higher among
populations with lower socioeconomic status. 3 In general, the
incidence of pediatric cancer is higher in industrialized countries than in developing countries, but patterns differ by cancer
type. 4, 5
Racial and ethnic disparities in survival for childhood and adolescent cancers have been noted previously.6, 7 Factors that may
be associated with these survival disparities include socioeconomic status, health insurance status, timely diagnosis and
quality of treatment and supportive care, and genetic factors.6
How Has the Occurrence of Pediatric Cancers
Changed over Time?
Trends in incidence rates
From 1975 to 2010, the overall incidence of pediatric cancer in
the US increased slightly, by an average of 0.6% per year.8 Specifi-
Figure 2. Trends in Pediatric Cancer Incidence Rates
by Site, Ages 0-19, 1975-2010
Figure 3. Trends in Pediatric Cancer Mortality Rates
by Site, Ages 0-19, 1975-2010
12
30
Acute
lymphocytic
leukemia
25
Brain and
CNS
20
NonHodgkin
lymphona
15
Hodgkin
lymphona
Malignant
bone tumors
10
Brain and
ONS
10
Acute
lymphocytic
leukemia
8
Rate per million
Rate per million
35
Bone and
joint
Soft tissue
including
heart
6
NonHodgkin
lymphona
4
Wilms tumor
5
Rhabdomyosarcomas
Kidney and
renal pelvis
2
Hodgkin
lymphoma
0
0
1975
1980
1985
1990
1995
2000
2005
2010
Year of diagnosis
1975
1980
1985
1990
1995
2000
2005
2010
Year of death
CNS = Central nervous system.
ONS = Other nervous system.
Note: lines represent Joinpoint fitted trends. Benign and borderline brain
tumors are not included. Malignant bone tumors include osteosarcoma and
Ewing sarcoma. Average annual percent change (APC) for cancers with
significant trends during most recent period: ALL (0.7), NHL (1.1), and
Hodgkin lymphoma (-0.7).
Average annual percent change (APC) for cancers with significant trends
during most recent period: ALL (-3.1 during 1988-2010), brain (-1.1 during
1975-2010), NHL (-4.1 during 1975-2010), soft tissue (-1.0 during 1979-2010),
kidney (-1.2 during 1992-2010), HL (-4.9 during 1975-2010).
Source: Surveillance, Epidemiology, and End Results (SEER) Program, 9 SEER
Registries, National Cancer Institute.
Source: National Center for Health Statistics, Centers for Disease Control and
Preventaion.
American Cancer Society, Surveillance Research, 2014
cally, incidence rates increased for 4 cancer types: acute
lymphocytic leukemia, acute myeloid leukemia, non-Hodgkin
lymphoma, and testicular germ cell tumors. Incidence rates
decreased for Hodgkin lymphoma and remained stable for other
cancers (Figure 2). Similar incidence patterns were observed in
Europe.9 Reasons for increases in incidence rates are largely
unknown. It is possible that some of this increase may be due to
changes in environmental factors. Improved diagnosis and
access to medical care over time may also have contributed, as
without medical care some children may die of infections or
other complications of their cancers without ever being diagnosed.10 The sharp rise in incidence of CNS tumors that occurred
in the 1980s is thought to reflect increased detection of tumors
as a result of the introduction of magnetic resonance imaging
(MRI) and stereotactic biopsy (biopsy accompanied by computer imaging), leading to more complete reporting (see section
on CNS tumors, page 32).11
Note: Lines are fitted trends based on Joinpoint analyses.
American Cancer Society, Surveillance Research, 2014
declines were observed for all sites in Figure 3 with the steepest
declines in Hodgkin lymphoma, non-Hodgkin lymphoma, and
acute lymphocytic leukemia. (Please note that the classification
of tumors in Figure 3 differs from that used in other tables and
figures because deaths are classified according to anatomic site
rather than International Classification of Childhood Cancers
group.)
What Is the Probability of Developing a
Childhood or Adolescent Cancer?
A child born in the United States has a 0.24% chance of developing cancer before age 15 and a 0.35% chance of developing cancer
before age 20.8 Another way of saying that is 1 in 408 children
will be diagnosed with cancer before age 15 and 1 in 285 children
will be diagnosed with cancer before age 20.
Trends in mortality rates
How Many Survivors of Pediatric Cancer Are
in the US?
Death rates for all childhood and adolescent cancers combined
declined steadily from 1975 to 2010 by an average of 2.1% per
year resulting in an overall decline of more than 50%. Mortality
An estimated 379,112 survivors of childhood and adolescent
cancer (diagnosed at ages 0-19) were alive in the US as of January
1, 2010. The top three cancer types among childhood cancers
Cancer Facts & Figures 2014 27
Table 1. Incidence, Mortality, and Survival Rates for Childhood and Adolescent Cancers by Sex and
Race/Ethnicity
Ages 0−14
Ages 15−19
Characteristic
Incidence,
Mortality, Observed
Incidence,
Mortality, Observed
2006-2010*
2006-2010*
Survival (%),
2006-2010*
2006-2010*
Survival (%),
2003-2009
2003-2009
Sex
Boys
Girls
178.023.3 81.3237.7 34.5 80.0
160.1 21.1 82.0235.5 24.7 85.4
Race/ethnicity
Non-Hispanic White
178.2
22.4
84.2
259.4
Non-Hispanic Black
134.5
21.9
75.3
171.9
Hispanic
167.3 22.6 80.3220.7
Asian American/131.9 19.1 78.3 167.8
Pacific Islander
American Indian/
117.1
15.8
78.5
200.1
Alaska Native†
29.0
85.9
30.6
76.8
32.4 75.8
25.6 80.4
24.0
77.3
*Rates are per 1,000,000 and age-adjusted to the 2000 US standard population. †Based on data from Indian Health Service Contract Health Service Delivery Areas.
Note: Incidence rates include benign and borderline brain tumors.
Source: Incidence: North American Association of Central Cancer Registries; Mortality: National Center for Health Statistics, Centers for Disease Control and Prevention;
Survival: Surveillance, Epidemiology and End Results (SEER) Program, 18 SEER Registries, National Cancer Institute.
American Cancer Society, Surveillance Research, 2014
survivors are acute lymphocytic leukemia, brain and CNS
tumors, and Hodgkin lymphoma (Table 2). Most (70%) survivors
of childhood and adolescent cancer are 20 years of age or older.
Approximately 1 in 530 adults between the ages of 20 and 39 is
a survivor of childhood cancer.
What Are the Risk Factors for Childhood and
Adolescent Cancer?
In contrast to cancers in adults, only a relatively small proportion of childhood cancers have known or preventable causes.
Ionizing radiation exposure is a well-recognized risk factor for
cancer in children and adolescents based on studies of medical
and environmental radiation exposure. The association between
low doses of radiation received by an unborn fetus during an
x-ray and subsequent risk of leukemia and other childhood cancers was demonstrated in the 1950s.12 As a result, precautions
have been taken to minimize radiation exposure during pregnancy, so this exposure is not likely to be of current concern.
Radiation exposure from diagnostic CT scans is higher and
more variable than exposures from conventional x-rays, and
studies suggest that radiation exposure early in life increases
long-term risk of leukemia and brain cancer.13 Health care providers are encouraged to limit the use of CT scans to situations
where there is a definite clinical indication and to optimize
scans using the lowest possible radiation dose.14
A number of recent studies have found that accelerated fetal
growth and higher birth weight are associated with increased
28 Cancer Facts & Figures 2014
risk for some childhood and adolescent cancers, including acute
lymphocytic leukemia, central nervous system (CNS) tumors,
Wilms tumor, non-Hodgkin lymphoma, and rhabdomyosarcoma, while lower birth weight has been associated with acute
myeloid leukemia and some CNS tumor subtypes.15-21 Although
numerous epidemiologic studies have investigated potential
environmental causes of childhood cancers, few strong or consistent associations have been found. The International Agency
for Research on Cancer has concluded there is sufficient
evidence that parental smoking increases the risk of hepatoblastoma (a type of liver cancer that occurs in young children)
and limited evidence for an association with childhood leukemia (particularly ALL).22 They also found limited evidence that
maternal exposure to paint is linked with childhood leukemia.22
Larger studies with the ability to examine specific histological
and/or molecular tumor subtypes may be needed to identify and
confirm potential environmental causes of childhood cancer.23
It is reasonable to suggest that pediatric tumors reflect, at least
in part, an inherent risk associated with the complex process of
normal development and chance rather than a response to an
external exposure. At the same time, it is known that the process
of development occurring in immature cells and organisms renders them more vulnerable to toxic exposures than mature cells,
and it is therefore important to minimize exposure to environmental agents with potential cancer-causing effects.24 For more
information on precautions to minimize exposures during pregnancy, see sidebar.
Table 2. US Childhood and Adolescent Cancer
Survivors by Cancer Site, as of January 1, 2010
Complete Prevalence Counts
by Age at Prevalence
Site Ages
0−19
Ages
20+
All
Ages
113,782
265,330
379,112
All Sites
Acute lymphocytic leukemia
Acute myeloid leukemia
Hodgkin lymphoma
Non-Hodgkin lymphoma
Brain and CNS Neuroblastoma
Wilms tumor
Bone tumors
Soft tissue sarcomas
Testicular germ cell tumors
Ovarian germ cell tumors
30,171
30,318
60,489
4,045
4,222
8,267
4,514
30,739
35,253
6,442
16,301
22,743
20,430
38,653
59,083
9,704 9,74819,452
7,831
15,707
23,538
3,766
9,366
13,132
6,849
24,599
31,448
2,755
17,890
20,645
2,464
14,628
17,092
CNS= central nervous system.
Note: Does not include benign and borderline brain tumors.
Source: Howlader, et al, 2013.8
American Cancer Society, Surveillance Research 2014
Some pediatric cancers, such as Wilms tumor and retinoblastoma, are associated with recognized genetic factors. Potential
environmental and genetic risk factors for pediatric cancers will
be discussed in relation to specific cancer types.
What Are Signs and Symptoms for Pediatric
Cancers?
Early diagnosis of cancer in children is often difficult because of
the similarity of symptoms to more common diseases of childhood.27 Parents should ensure that children have regular
medical checkups and be alert to any unusual signs or persistent symptoms. Some common symptoms of childhood cancer
that should alert parents and health care providers include an
unusual mass or swelling; unexplained paleness or loss of
energy; a sudden tendency to bruise; a persistent, localized pain
or limping; a prolonged, unexplained fever or illness; frequent
headaches, often with vomiting; sudden eye or vision changes;
and excessive, rapid weight loss. Information on symptoms for
specific cancer types is discussed in the next section.
Major Cancer Types
Leukemia and lymphoma
Leukemia is a cancer of blood-forming cells arising in the bone
marrow. Lymphomas are cancers of a certain type of white
blood cell (lymphocyte) that can arise anywhere lymphocytes
can be found, including bone marrow, lymph nodes, the spleen,
the intestines, and other areas of the lymphatic system. Leuke-
Precautions to Minimize Exposures during
Pregnancy
Some of the changes in cells that lead to the development of
childhood cancer may take place during pregnancy. Radiation
exposures, both in utero and during early life, have been found
to increase cancer risk. It is also possible that environmental
exposures to either parent prior to the child’s conception
may influence childhood cancer risk. Research studies have
not identified strong and consistent preventable causes of
childhood cancer (other than exposure to ionizing radiation).
However, since the developing fetus is more sensitive to some
exposures than adults, women are advised to take precautions to minimize exposures during pregnancy. With respect
to environmental exposures, the Office of Women’s Health,
Department of Health and Human Services recommends that
during pregnancy, women should avoid exposure to:25
• Lead – Found in some water and paints, mainly in homes
built before 1978
• Mercury – The harmful form is found mainly in large, predatory fish.
• Arsenic – High levels can be found in some well water.
• Pesticides – Both household products and agricultural
pesticides
• Solvents – Such as degreasers and paint strippers and
thinners
• Cigarette smoke
Additional precautions include:
• Clean in only well-ventilated spaces. Open the windows or
turn on a fan.
• Check product labels for warnings for pregnant women and
follow instructions for safe use.
• Do not clean the inside of an oven while pregnant.
• Leave the house if paint is being used, and don’t return until
the fumes are gone.
The National Institute for Occupational Safety and Health
provides additional recommendations for women who are
employed in occupations with potential toxic exposures.26
mias and lymphomas are classified according to the type of cell
that is exhibiting uncontrolled growth.
The two most common types of leukemia in children and adolescents are acute lymphocytic leukemia (ALL) and acute
myeloid leukemia (AML). Chronic leukemias are very rare in
children and adolescents. ALL accounts for about 80% of leukemia cases in children and 56% of leukemia cases in adolescents.
Acute myeloid leukemia (AML) is less common in children than
ALL, comprising about 15% of leukemia cases in children and
31% in adolescents. There are two types of lymphoma: Hodgkin
Cancer Facts & Figures 2014 29
Acute lymphocytic leukemia (ALL)
An estimated 2,670 children and 410 adolescents will be diagnosed with ALL in 2014 (Figure 1, page 26). ALL is the most
common cancer in children, accounting for 26% of cancers diagnosed in ages 0-14. Similar to lymphomas, ALL is a cancer of
lymphocytes. Most often ALL in children involves B lymphocytes, the type of lymphocyte that makes antibodies to
infections, but it can also involve T lymphocytes, which help the
body fight disease in other ways.
ALL occurs in children throughout the world, but it is more
common in industrialized countries than in developing countries. In the US, ALL is more common in boys than in girls and in
Hispanic and white children than in African American children
(Table 3). In industrialized countries, there is a sharp peak in
ALL incidence rates at ages 2-4, which is not apparent among
children in developing countries.10 The characteristic age peak
for ALL in the US is striking for white and Hispanic children, but
less so for African American children (Figure 4).
There is evidence that some cases of ALL arise in utero, including a frequent concordance of ALL in identical twins.28 Inherited
risk factors associated with ALL include trisomy 21 (Down syndrome), which confers a 10- to 20-fold increased risk, certain
genetic syndromes (Bloom syndrome, Fanconi anemia, and
Nijmegen breakage syndrome) and congenital immunodeficiency diseases.28 Although many epidemiologic studies have
sought to find the causes of ALL, few environmental agents are
definitively linked with this disease. According to the International Agency for Research on Cancer, there is limited evidence
that parental smoking and maternal exposure to paint increase
the risk for childhood leukemia (particularly ALL).22 Higher
birth weight has also been associated with higher ALL risk in a
number of studies.23, 29 Recent studies suggest that early exposure to infections (such as occurs in infant day care settings)
may be protective for childhood ALL.30, 31
Improved treatment for ALL in childhood has increased the
5-year survival rate from 57% in 1975-1979 to 90% in 2003-2009
(Table 4, page 35). Treatment is generally in three phases, and
consists of 4-6 weeks of induction chemotherapy (chemotherapy
given to induce remission) administered in the hospital, followed by several months of consolidation chemotherapy and 2-3
years of maintenance chemotherapy.28 The central nervous system (CNS) is a common site for relapse, so children receive
specific treatment to prevent this (CNS prophylaxis). Bone marrow transplantation is recommended for some children whose
leukemia has high- risk characteristics at diagnosis and for children who relapse after remission.28 It may also be used if the
30 Cancer Facts & Figures 2014
Figure 4. Age-specific Incidence Rates of Acute
Lymphocytic Leukemia (ALL) by Race/ethnicity and
Acute Myeloid Leukemia (AML) All Races Combined,
2001-2010
120
ALL - Hispanic
ALL - White
ALL - African American
AML
100
Rate per million
lymphoma (HL) and non-Hodgkin lymphoma (NHL). HL
accounts for about 38% of lymphomas in children and about 65%
in adolescents, while NHL accounts for 62% of lymphomas in
children and 35% of lymphomas in adolescents.
80
60
40
20
*
0
*
*
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
Age at diagnosis
Note: Data not shown for ages with fewer than 25 cases. Data for whites
and African Americans exclude Hispanic ethnicity. Due to sparse data for ALL
in African Americans for some ages, data are shown for combined age
groups: 7-10, 11-14, 15-19 marked by astericks.
Source: Surveillance, Epidemiology, and End Results (SEER) Program, 18 SEER
Registries, National Cancer Institute.
American Cancer Society, Surveillance Research, 2014
leukemia does not go into remission after a successive course of
induction chemotherapy. Successful treatment of ALL requires
multidisciplinary teams to provide supportive care and careful
monitoring for infection and adequate nutrition.
Disparities in survival between white and African American
children treated for ALL have been documented in a number of
studies.4, 5, 32 Notably, this disparity has diminished in recent
years, from a 21% difference in 5-year survival during 1980-84
(68% vs. 47%, in whites and African Americans, respectively) to a
6% difference in 2003-2009 (90% vs. 84%, respectively).33
Long-term adverse health effects among children treated for
ALL can include neurocognitive defects, growth deficiency, and
increased risk of second cancers, including AML and CNS
tumors.34 Early forms of CNS prophylaxis that combined high
doses of radiation and intrathecal (injected into the fluid surrounding the brain and spinal cord) chemotherapy had a high
risk of damage to brain tissue resulting in neurocognitive
defects; less toxic therapies that avoid the use of radiation have
reduced, but not eliminated these risks. Radiation therapy is
now used in only a small fraction of ALL patients at high risk of
CNS relapse. Children treated with anthracyclines are at risk for
late cardiac effects.28
Acute myeloid leukemia
An estimated 500 children and 230 adolescents will be diagnosed with AML in 2014. AML arises from blood-forming cells,
most often those that would turn into white blood cells (except
lymphocytes). The incidence of AML is highest in the first two
years of life (Figure 4). Incidence rates for AML are slightly
higher in Hispanic children compared to other racial/ethnic
groups (Table 3).
Radiation exposure is an established risk factor for childhood
leukemia, and some studies have found associations of childhood leukemia with specific chemicals, such as benzene, and
drugs used to treat cancer, such as alkylating agents and topoisomerase II inhibitors; these are more strongly associated with
AML than ALL.35
Children with AML and high white blood cell counts may
develop symptoms due to impaired transit of cancer cells (blasts)
through small blood vessels.36 Many AML patients are prone to
excessive bleeding and other blood clotting disorders. Death
occurs during the first 2 weeks after diagnosis in 2-4% of children with AML.36 Treatment for AML consists of induction
chemotherapy, CNS prophylaxis, and post-remission therapy.
Stem cell transplant has been investigated in clinical trials and
has been shown to improve survival rates for some children with
AML.36 Treatment toxicity and long-term effects for AML are
similar to those for ALL; however, AML less often requires treatment or prophylaxis of the CNS, so side effects related to
radiation of the brain are not as common. 36 The 5-year survival
rate for AML for children diagnosed in 2003-2009 was 64%
(Table 4, page 35). Survival rates for AML have improved in
recent decades, but remain lower than for ALL.
Hodgkin lymphoma
An estimated 380 children and 800 adolescents will be diagnosed with HL in 2014. HL is a cancer of lymphocytes that often
starts in the lymph nodes in the chest, neck, or abdomen. There
are two major types of HL: classic, which is the most common
and is characterized by the presence of multinucleated giant
cells called Reed-Sternberg cells, and nodular lymphocyte predominant, which is characterized by so called “popcorn cells.”
This type is rare and tends to be slower growing than the classic
form.37
HL is rare among children younger than age 5; incidence rates
increase slightly up to about age 10 and then rise rapidly through
Table 3. Pediatric Cancer Incidence Rates* by Sex and Race/Ethnicity, Ages 0-19, US, 2006-2010
All Races
Non-Hispanic
Non-Hispanic
Hispanic
Boys Girls
White
Black
All ICCC sites
Leukemia
Acute lymphocytic leukemia
Acute myeloid leukemia
Lymphomas and reticuloendothelial neoplsams
Hodgkin lymphoma
Non-Hodgkin lymphoma
Brain and CNS
Ependymoma
Astrocytoma
Medulloblastomas
Neuroblastoma and ganglioneuroblastoma
Retinoblastoma
Wilms tumor
Hepatic tumors
Bone tumors
Osteosarcoma
Ewing sarcoma
Rhabdomyosarcoma
Testicular germ cell tumors
Ovarian germ cell tumors
Thyroid carcinoma
Melanoma
196.7
182.3
52.043.1
38.4
30.2
7.9
8.0
29.8
20.7
12.9
11.8
15.1
7.7
45.5
45.9
3.2
2.4
16.5
15.5
5.1
3.3
8.5
7.6
2.93.3
5.3
6.3
2.8
1.8
9.8
7.7
5.5
4.5
3.3
2.4
5.44.2
9.9
---
---
4.4
3.0
12.6
3.75.8
201.7
46.9
34.2
7.7
27.4
13.9
11.9
50.9
3.0
18.8
4.8
9.7
2.7
6.2
2.2
9.2
4.6
3.7
4.8
10.9
3.4
9.1
7.1
146.1
29.9
18.3
7.1
22.2
10.3
11.4
36.1
2.1
12.3
2.7
6.8
3.4
6.7
1.7
7.2
5.7
0.5
5.5
1.4
5.3
2.8
0.5
Asian American/
Pacific Islander
184.2
59.6
44.9
8.7
21.6
10.2
9.5
38.7
2.7
12.0
3.7
5.2
3.4
4.5
2.5
8.9
5.4
2.5
4.5
13.6
6.1
7.2
1.4
140.8
39.4
28.7
8.0
18.3
7.5
10.0
28.6
2.6
9.1
3.3
5.9
3.1
2.9
3.0
6.7
3.9
2.0
2.9
6.1
4.7
6.9
†
ICCC=International classification of childhood cancers. CNS=Central nervous system.
*Rates are per 1,000,000 and age-adjusted to the 2000 US standard population. †Statistic not displayed if based on fewer than 25 cases.
Note: Rates include benign and borderline brain tumors.
Source: North American Association of Central Cancer Registries. Data are included from all US states and the District of Columbia except Arkansas, Minnesota, Nevada,
Ohio, and Virginia. Rates by Hispanic ethnicity also exclude data from Massachussets.
American Cancer Society, Surveillance Research 2014
Cancer Facts & Figures 2014 31
Figure 5. Age-specific Incidence Rates of NonHodgkin Lymphoma (NHL) and Hodgkin
Lymphoma (HL), 2001-2010
Rate per million
50
HL
NHL
40
30
20
10
0
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
Age at diagnosis
Note: Data not shown for ages with fewer than 25 cases.
Source: Surveillance, Epidemiology, and End Results (SEER) Program, 18 SEER
Registries, National Cancer Institute.
American Cancer Society, Surveillance Research, 2014
adolescence (Figure 5). HL is the most common cancer in adolescents, accounting for about 15% of cancers diagnosed between
ages 15 and 19 (Figure 1, page 26). Incidence rates for HL are
about 30% higher among white children compared to African
American and Hispanic children (Table 3, page 31). Asian American/Pacific Islanders have the lowest incidence rate for HL. Risk
factors for HL include Epstein Barr virus (EBV) or a having a personal history of mononucleosis and human immunodeficiency
virus (HIV) infection.
Survival rates for HL increased from 87% in 1975-1979 to 97% in
2003-2009 (Table 4, page 35). HL is highly sensitive to radiation,
and cure can be achieved in some patients by radiation therapy
alone, although this is seldom the preferred treatment in children and adolescents. The high dose of radiation used to treat
HL in past decades was found to be damaging to organs such as
the lungs and heart, so current therapies usually combine lower
doses of chemotherapy and radiation to achieve a high cure rate
with less toxicity.37 Long-term and late effects of treatment may
include pulmonary and cardiac diseases, thyroid abnormalities,
infertility, and second cancers. Girls age 10 and older and young
women treated with radiation to the chest for HL have an exceptionally high relative and absolute risk of developing breast
cancer.38, 39 The American Cancer Society recommends annual
MRI in addition to mammographic screening for women were
treated for HL.40
Non-Hodgkin lymphoma
An estimated 620 children and 420 adolescents will be diagnosed with NHL in 2014. The most common subtypes among
children and adolescents in the US are Burkitt lymphoma (BL)
(19%), diffuse large B-cell lymphoma (DLBCL) (22%), lympho-
32 Cancer Facts & Figures 2014
blastic lymphoma (20%), and anaplastic large cell lymphoma
(10%).41 Both the incidence and distribution of NHL subtypes
vary throughout the world. For example, in equatorial Africa,
lymphomas account for nearly one-half of childhood cancers,
reflecting the very high incidence of BL.10 The high incidence of
BL in equatorial Africa is associated with high rates of co-infection with EBV and malaria.10 BL in Africa, also known as
endemic BL, is much more common in boys than in girls and
often arises in the jaw or around the eyes. In the US, the incidence of BL is also much higher in boys than in girls, but occurs
most frequently in the abdomen and is less common in African
American than in white children (Table 3, page 31).
EBV infection is also associated with many other types of NHL,
although not as strongly as for BL in Africa. Immunosuppression from a variety of causes increases the risk of NHL, including
inherited immunodeficiency disorders, HIV infection, and
post-transplantation immune suppression.42 Multiagent chemotherapy is the main form of treatment for most types of NHL.
The dramatic improvement in survival rates for adults with
DLBCL when rituximab (a monoclonal antibody) is administered with multiagent chemotherapy has stimulated clinical
trials to evaluate the role of monoclonal antibodies in treatment
of pediatric DLBCL.42 Survival rates for NHL in children and
adolescents have increased dramatically in recent decades: from
47% in 1975-1979 to 85% in 2003-2009 (Table 4, page 35). Longterm and late effects of NHL include heart damage, cognitive
effects, infertility, and low bone density.
Brain and central nervous system tumors (CNS
tumors)
An estimated 2,240 children and 540 adolescents will be diagnosed with malignant CNS tumors in 2014. CNS tumors are the
second most common cancer in children, accounting for 21% of
cases, and the third most common cancer type in adolescents,
accounting for 10% of cases. CNS tumors are classified by the
cells and tissues in which they originate and their location and
grade, ranging from I (low) to IV (high). Symptoms of benign
tumors and side effects of treatment can be quite severe; therefore since 2004, cancer registries have been collecting data for
benign as well as malignant CNS tumors. Statistics with benign
and malignant tumors combined are used in this report when
available. In 2014, an estimated 730 children and 630 adolescents will be diagnosed with benign and borderline malignant
brain tumors.
Figure 5 provides age-specific incidence rates for three common
categories of CNS tumors in children and adolescents:
• Astrocytoma, the most common type of CNS tumor, accounts
for 35% of CNS tumors in ages 0-19. These tumors arise from
brain cells called astrocytes. Astrocytomas range from low
grade to high grade. Pilocytic astrocytoma, the most common type of astrocytoma in children, is a low-grade tumor
Figure 6. Age-specific Incidence Rates for CNS
Tumors, US, 2006-2010
25
Astrocytoma
Medulloblastoma
Ependymoma
Rate per million
20
15
10
5
0
0-4
5-9
10-14
15-19
Age at diagnosis
CNS=Central nervous system.
Source: North American Association of Central Cancer Registries. Data are
included from all US states and the District of Columbia except Arkansas,
Minnesota, Nevada, Ohio, and Virginia.
American Cancer Society, Surveillance Research, 2014
that typically arises in the cerebellum. Fibrillary astrocytoma, another common type of astrocytoma in children, is
usually found in the mid-brain, has less well-defined borders
and can spread throughout both sides of the brain.43
• Medulloblastoma most commonly diagnosed in children
younger than 10 (Figure 6). It is a highly invasive embryonal
tumor that arises in the cerebellum and has a tendency to
spread throughout the central nervous system early in its
course.44
• Ependymoma is a tumor that begins in the ependymal lining
of the ventricular system (fluid-filled cavities in the brain)
or the central canal of the spinal cord. Ependymomas range
from low to high grade.43
The symptoms of brain tumors are varied, as is the time course
over which symptoms develop and increase in severity. Signs
and symptoms of brain cancer depend on the tumor location,
the developmental stage and communication ability of the child
or young person, and whether intracranial pressure is raised.
Trends in CNS tumors have been of interest because of a sharp
increase in overall incidence in the mid-1980s (Figure 2, page
27), with significant increases in incidence rates for pilocytic
astrocytoma, primitive neuroectodermal tumor (PNET)/medulloblastoma, and mixed glioma.11,43,45 Many experts believe that
this short-term increase in incidence resulted from the introduction of MRI for evaluating children with neurologic
conditions and increased use of computer image-guided biopsies to document tumors that could not otherwise be biopsied.
Furthermore, the rate of increase in pilocytic astrocytoma was
similar to the rate of decrease for astrocytomas NOS (not otherwise specified), suggesting an improvement in classification.46
After the increase in the mid-1980s, the incidence rate of CNS
tumors stabilized (Figure 2, page 27).
The cause of brain tumors in childhood is unclear.47 Children
with certain genetic syndromes (e.g., Turcot syndrome,
Li-Fraumeni syndrome, neurofibromatosis type 1, and neurofibromatosis type 2) have increased risk of brain and CNS
tumors.43 High-dose therapeutic radiation is a recognized cause
of brain tumors, and children who receive cranial irradiation for
ALL or other cancers have an excess risk of brain and CNS
tumors. A number of studies have also found associations
between consumption of cured meats during pregnancy and
childhood brain tumors.48-51
Treatment of brain and other CNS tumors depends on the cancer type, grade, location, size, and other prognostic factors.
Whenever possible, surgery is performed to remove as much of
the tumor as possible while avoiding damage to healthy tissue.
Optimal therapy, which may include chemotherapy and/or radiation, requires coordinated efforts of pediatric cancer specialists
in fields such as neurosurgery, neuropathology, radiation oncology, and pediatric oncology. Late effects can include impaired
growth and neurologic development following radiation therapy, especially in younger children. For this reason, children
under age 3 usually receive chemotherapy first with delayed
and/or reduced radiation. Radiation is not always needed for
low-grade tumors.43
Survival rates vary depending on tumor type, location, and
grade. Trends in survival rates over time are available for malignant brain tumors only (Table 4, page 35). While there has been
progress in survival for CNS tumors overall, there has been little
progress for some subtypes, such as DIPG (diffuse intrinsic pontine glioma), for which the median survival time after diagnosis
remains less than one year. 51
Embryonal tumors
Embryonal tumors arise from cells in developing tissues and
organ systems of a fetus. These tumors are usually diagnosed in
children before age 5. Age-specific incidence rates for three
common types of embryonal tumors in children (neuroblastoma, Wilms tumor, and retinoblastoma) are presented in
Figure 7 (page 34). Other embryonal tumors, including medulloblastoma and rhabdomyosarcoma, are discussed in other
sections of this report.
Neuroblastoma
An estimated 710 cases of neuroblastoma will be diagnosed
among children (ages 0-14) in 2014. It is the third most common
childhood cancer and represents 7% of the total cases in this age
group. Neuroblastoma develops from certain types of very primitive nerve cells in the embryo and is the most common cancer
diagnosed during the first year of life; it is very uncommon after
age 10. The incidence of neuroblastoma is slightly higher in boys
than girls and substantially higher in whites than children of
other races/ethnicities (Table 3, page 31). Although epidemiologic studies have investigated environmental factors that may
Cancer Facts & Figures 2014 33
Neuroblastoma can spread through the lymph system and
blood, and over half of children have regional or distant stage
disease at diagnosis.53 A rare form of neuroblastoma (stage 4S)
occurs in infants with a specific pattern of metastatic disease
and often regresses with little or no treatment.54 Depending on
stage and other prognostic factors, children with neuroblastoma are most commonly treated with surgery and/or
chemotherapy and radiation therapy; patients with high-risk
disease may receive high-dose chemotherapy followed by stem
cell transplant.53 Overall survival rates for neuroblastoma have
increased from 54% in 1975-1979 to 79% in 2003-09 (Table 4).
However, survival remains poor for children with high-risk disease. Children treated for high-risk disease also have the greatest
risk of treatment-related complications, including severe hearing loss, infertility, cardiac toxicity, and second cancers related
to the use of high-dose chemotherapy.53
Wilms Tumor
An estimated 510 cases of Wilms tumor will be diagnosed
among children in 2014. Also called nephroblastoma, Wilms
tumor is an embryonal tumor of the kidney that usually occurs
in children under age 5 (Figure 7). The vast majority (92%) of kidney tumors in this age group are Wilms tumor.41 The incidence
rate of Wilms tumor is slightly higher in girls than boys and in
African American children compared to children of other races/
ethnicities (Table 3, page 31). Wilms tumor is bilateral (occurring in both kidneys) in about 5-10% of cases.55 About 10% of
cases are associated with a birth defect such as urogenital tract
abnormalities.56 Epidemiologic studies have not identified
strong or consistent environmental risk factors for Wilms
tumor.
The majority of children with Wilms tumor are diagnosed with
an asymptomatic abdominal mass that is incidentally noted
while bathing or dressing the child.57 Wilms tumor may spread
locally or through the bloodstream; distant metastases are
uncommon at diagnosis. Treatment involves surgery and may
include radiation and/or chemotherapy. In addition to stage,
histology (how the cancer cells look under the microscope) and
age at diagnosis are important prognostic factors.57 Survival
rates for Wilms tumor increased from 75% in 1975-1979 to 90%
in 2003-2009 (Table 4). Late effects observed among survivors of
Wilms tumor include heart damage, diminished lung and kidney function, reduced fertility and pregnancy complications
among girls treated with radiation, and an increased risk of second cancers.57
Retinoblastoma
An estimated 280 children will be diagnosed with retinoblastoma in 2014. Retinoblastoma is a cancer that starts in the retina,
the very back part of the eye. Retinoblastoma usually occurs in
children under age 5 and accounts for 6% of cancers in this age
group (Figure 7). The incidence of retinoblastoma is similar in
boys and girls, does not vary substantially by race and ethnicity,
and has been stable in the US population since 1975 (Table 3,
page 31, Figure 2, page 27). Symptoms of retinoblastoma may
include “white pupil,” in which the pupil of the eye appears white
instead of red when light shines into it, eye pain or redness, and
vision problems.
Most cases of retinoblastoma are due to a mutation in the RB1
gene. Approximately one-third of retinoblastomas are inherited,
meaning that the RB1 mutation is in all of the body’s cells (i.e., a
germline mutation).58 Genetic counseling should be an integral
part of the therapy for the family of a patient with retinoblastoma.58 Patients who carry a germline RB1 mutation have an
increased risk of second cancers, especially if they receive radiation therapy.59
The type of treatment required for retinoblastoma depends
largely on the extent of the disease within the eye and whether
the disease has spread beyond the eye. Treatment options consider both cure and preservation of sight. Small tumors may
sometimes be treated with cryotherapy (freezing), laser therapy,
or thermotherapy (heat laser). Patients with more advanced disease, but that only involves one eye without spread to nearby
tissues, are often treated with surgery to remove the eye (enucleation), which may be the only treatment needed.58 Children with
bilateral (both eyes are affected) disease, and some children
with unilateral disease, may be treated with chemotherapy to
shrink tumors to a size where local treatment is effective.
Figure 7. Age-specific Incidence Rates for
Embryonal Tumors, US, 2006-2010
60
Neuroblastoma
Retinoblastoma
Wilms tumor
50
40
Rate per million
be associated with neuroblastoma, no strong or consistent risk
factors have been identified. A family history of neuroblastoma
is present in 1% to 2% of cases. Children who have siblings with
neuroblastoma are nearly 10 times more likely to be diagnosed
with the disease than children without a family history.52
30
20
10
0
<1
1-4
5-9
Age at diagnosis
Source: North American Association of Central Cancer Registries. Data are
included from all US states and the District of Columbia except Arkansas,
Minnesota, Nevada, Ohio, and Virginia.
American Cancer Society, Surveillance Research, 2014
34 Cancer Facts & Figures 2014
Table 4. Pediatric Cancer Five-year Observed
Survival Rates for Two Time Periods, Ages 0-19
All ICCC sites
Leukemia
Acute lymphocytic leukemia
Acute myeloid leukemia
Lymphomas and reticuloendothelial neoplsams
Hodgkin lymphoma
Non-Hodgkin lymphoma
Brain and CNS
Ependymoma
Astrocytoma
Medulloblastoma
Neuroblastoma and ganglioneuroblastoma
Retinoblastoma
Wilms tumor
Hepatic tumors
Bone tumors
Osteosarcoma
Ewing sarcoma
Rhabdomyosarcoma
Testicular germ cell tumors
Ovarian germ cell tumors
Thyroid carcinoma
Melanoma
Year of Diagnosis
1975-792003-09*
%%
63
83
4884
57
90
21
64
72
91
87
97
47
85
59
75
37
81
69
85
47
70
54
79
9299
75
90
25
74
49
73
45
71
42
72
4964
74
96
75
94
99
98
8395
ICCC=International classification of childhood cancers.
CNS=Central nervous system.
*Cases were followed through 2010.
Note: Does not include benign and borderline brain tumors.
Source: Surveillance, Epidemiology, and End Results (SEER) program, 9 SEER
registries, National Cancer Institute.
American Cancer Society, Surveillance Research, 2014
Patients with more advanced disease are treated with chemotherapy and sometimes surgery and/or radiation.59 Recent
studies have investigated the efficacy of intra-arterial chemotherapy with promising results.60 Five-year survival rates for
retinoblastoma have increased from 92% in 1975-1979 to 99% in
2003-2009 (Table 4). Late effects of retinoblastoma include visual
impairment and increased risks of second cancers, including
bone and soft tissue sarcomas and melanoma.61
Bone tumors and soft tissue sarcomas
Sarcomas are tumors that develop from connective tissues in
the body, such as muscles, fat, bones, membranes that line the
joints, or blood vessels. An estimated 450 children and 370 adolescents will be diagnosed with bone tumors in 2014. The two
most common types of bone tumors in children and adolescents
are osteosarcoma and Ewing sarcoma. The most common type
of soft tissue sarcoma is rhabdomyosarcoma, which will be diagnosed in an estimated 340 children in 2014. Age-specific
incidence rates for these three types of sarcoma are presented in
Figure 8, page 36. Another type of soft tissue sarcoma, Kaposi
sarcoma, while extremely rare among children in the US, is very
common in children in Africa due in part to the high prevalence
of HIV infection.4, 5
Osteosarcoma
Osteosarcoma is the most common type of bone cancer in children and adolescents. The incidence of osteosarcoma increases
with age throughout childhood and adolescence; it is very rare
among children under age 5 (Figure 8, page 36). The incidence of
osteosarcoma is slightly higher in boys than girls and also higher
in African American and Hispanic children than in white and
Asian American/Pacific Islander children (Table 3, page 31).
Osteosarcoma arises from primitive bone-forming stem cells
and usually develops in areas where the bone is growing rapidly,
such as near the ends of the long bones around the knee. Osteosarcoma commonly appears as sporadic pain in the affected
bone that may worsen at night or with activity, with progression
to local swelling.62
Prior radiation treatment for another tumor increases the risk of
osteosarcoma. Radiation-associated osteosarcomas usually
occur 7 to 15 years after treatment of the primary tumor. Some
studies have found that taller children are at greater risk of
osteosarcoma, while others have not.63 The incidence of osteosarcoma is increased among individuals with the hereditary
form of retinoblastoma and Li-Fraumeni syndrome, as well as
several other genetic syndromes.62
About 20% of patients have detectable metastases (distant
spread) at diagnosis, most commonly in the lung.64 Nearly all
patients receive systemic therapy (chemotherapy given through
the blood stream to reach cancer cells throughout the body) due
to the high risk of metastases. Current standard therapy consists of neoadjuvant chemotherapy to shrink the tumor, followed
by surgery and adjuvant chemotherapy.62 Amputation is rarely
needed. The 5-year survival rate for osteosarcoma was 71% in
2003-09, up from 45% in 1975-79 (Table 4). Therapy-related late
effects can include heart damage, hearing loss, kidney dysfunction, second cancers, and infertility. Patients treated for
osteosarcoma may also have physical limitations resulting from
surgery.62
Ewing sarcoma
Ewing sarcoma is the second most common malignant bone
tumor in children and adolescents. It is more common among
older children and adolescents than young children (Figure 8,
page 36). Notably, incidence rates of Ewing sarcoma in whites
are nearly 7.5 times higher than in African Americans, and moderately higher than in Hispanics and Asian American/Pacific
Islanders (Table 3, page 31). Similar differences in incidence are
observed globally.10 Ewing sarcoma is a highly aggressive cancer, and it is characterized by a mutation in the EWSR1 gene.65
Cancer Facts & Figures 2014 35
9
Rhabdomyosarcoma
Ewing sarcoma
Osteosarcoma
Rate per million
8
7
6
5
4
3
2
1
0
0-4
5-9
10-14
15-19
Age at diagnosis
Source: North American Association of Central Cancer Registries. Data are
included from all US states and the District of Columbia except Arkansas,
Minnesota, Nevada, Ohio, and Virginia..
American Cancer Society, Surveillance Research, 2014
Ewing sarcomas arise about equally in bones of the extremities
and those in other parts of the body, and may also arise in soft
tissues.66 The first symptom is usually pain at the tumor site,
sometimes along with a mass or swelling. Metastases are present in about 25% of patients at diagnosis; the most common
metastatic sites are the lungs, bone, and bone marrow.67 Treatment for Ewing sarcoma typically involves induction
chemotherapy followed by local therapy (surgery and/or radiation) and adjuvant chemotherapy. There is continuing
uncertainty about whether surgery or radiation therapy is preferred for local control, and sometimes radiation therapy is used
both before and after surgery.68 Survival rates for Ewing sarcoma have increased from 42% in 1975-1979 to 72% in 2003-09
(Table 4, page 35). Ewing sarcoma survivors are at increased risk
for developing a second cancer, heart and lung conditions, infertility, and musculoskeletal problems.68
Rhabdomyosarcoma
Rhabdomyosarcoma is a cancer made up of cells that normally
develop into skeletal muscles. This cancer accounts for 3% of
childhood cancers and 2% of adolescent cancers. There are two
major subtypes of rhabdomyosarcoma: embryonal rhabdomyosarcoma (about 75% of cases), which is most common in children
under age 5, and alveolar rhabdomyosarcoma (about 16% of
cases), for which incidence does not vary by age in children and
adolescents.69 Embryonal rhabdomyosarcoma most commonly
occurs in the head and neck, whereas alveolar rhabdomyosarcoma is most common in the trunk and extremities. The first
symptoms often include pain and/or a mass or swelling at the
site of origin. Rhabdomyosarcoma is associated with a number
of genetic syndromes, including Li-Fraumeni syndrome and
neurofibromatosis type 1.
All patients with rhabdomyosarcoma receive several types of
treatment, including chemotherapy in conjunction with surgery, radiation, or a combination thereof.70 Although survival for
rhabdomyosarcoma has improved (from 49% in 1975-1979 to
64% in 2003-09), it remains lower than many other pediatric
cancers (Table 4, page 35). Treatments for patients with intermediate and high-risk disease continue to be studied in clinical
trials in hopes of achieving better outcomes.71 Late effects of
treatment for rhabdomyosarcoma depend on whether radiation
therapy was given and the specific chemotherapy agents
received, which have varied over time.
Gonadal germ cell tumors
Gonadal germ cell tumors are a diverse group of tumors that
arise from either the ovaries in girls or the testicles in boys.
These tumors are more common in adolescents than in young
children and occur more frequently in boys than girls (Figure 9).
Incidence rates vary by race/ethnicity, with Hispanic children
having the highest rates and African American children having
the lowest (Table 3, page 31).
Ovarian germ cell tumors
An estimated 110 adolescent girls will be diagnosed with ovarian germ cell tumors in 2014. Ovarian germ cell tumors are more
common in older girls (ages 10-14) and adolescents than in
younger girls (Figure 9). The risk of ovarian tumors is increased
among individuals with several genetic syndromes involving sex
chromosomes, including Turner syndrome and Swyer syndrome.72 Ovarian germ cell tumors often cause abdominal pain,
swelling, and weight gain.73 Surgery is the primary treatment;
removal of only the affected ovary and fallopian tube is an option
for most patients who wish to preserve fertility. Patients with
early stage disease may be monitored after surgery, while those
Figure 9. Age-specific Incidence Rates for
Gonadal Germ Cell Tumors, US, 2006-2010
40
Testicular germ cell tumors
Ovarian germ cell tumors
35
Rate per million
Figure 8. Age-specific Incidence Rates for Bone
and Soft Tissue Sarcomas, US, 2006-2010
30
25
20
15
10
5
0
0-4
5-9
10-14
15-19
Age at diagnosis
Rates are not shown when based on fewer than 25 cases.
Source: North American Association of Central Cancer Registries. Data are
included from all US states and the District of Columbia except Arkansas,
Minnesota, Nevada, Ohio, and Virginia.
American Cancer Society, Surveillance Research, 2014
36 Cancer Facts & Figures 2014
with more advanced disease receive chemotherapy. The 5-year
survival rate is 94% (Table 4, page 35). The chemotherapy regimens most commonly used for ovarian germ cell tumors may
cause hearing loss and kidney damage.74
Testicular germ cell tumors
An estimated 430 testicular germ cell tumors (TGCT) will be
diagnosed in boys ages 15-19 in 2014, making it the fourth most
common cancer in this age group. Some TGCT also occur in
boys under the age of 4 (Figure 9). The incidence of TGCT is
higher among whites and Hispanics than among African Americans (Table 3, page 31). There are two major types of TGCT:
non-seminomas (accounting for the majority of TGCT in adolescents) and seminomas.75 A lump on the testicle is usually the
first sign and often leads to diagnosis at an early stage. Risk factors for TGCT include a history of an undescended testicle and a
family history of testicular cancer.74 Removal of the affected testicle is the primary treatment for all TGCT; subsequent treatment
varies by stage. Early stage cancers (stages I and II) may be
observed closely after surgery, while those with continued elevation of serum markers should undergo radiation therapy.
Later-stage cancer requires chemotherapy. Survival rates for
testicular cancer have improved substantially since the mid1970s (from 74% to 96% in 2003-2009), and most patients have a
good prognosis (Table 4, page 35).
Side Effects and Support during Cancer
Therapy
Children with cancer may suffer from pain and other symptoms
due to the cancer itself, pain and anxiety related to medical procedures and hospitalizations, physical side effects of treatment,
separation anxiety, and psychological distress.76,77 Pediatric
nurse oncologists and other members of the health care team
play important supportive roles in assessing and managing
pain, distress, and other symptoms that may arise in children
and adolescents undergoing cancer treatment. Optimal care for
children with cancer may also involve consultation with specialists, such as psychologists and social workers, who are trained
and experienced in methods to reduce pain and suffering for
pediatric cancer patients and to provide psychosocial and other
support to patients, siblings, parents, and other caregivers.76, 78
Major pediatric centers that treat cancer in children also have
palliative care teams that specialize in managing pain and other
distressing symptoms. Palliative care, also called supportive
care, should be provided throughout the course of pediatric cancer treatment and continued as needed to minimize pain and
suffering, improve patient and family quality of life, facilitate
decision making, and assist in care coordination between clinicians and across sites of care.78, 79
Caring for a child who is undergoing cancer treatment is difficult for many families. Psychosocial support for parents and
other family members is an important component of care. 81
Oncology social workers, psychologists, child life specialists,
and other staff at pediatric cancer centers provide psychosocial
support to families, as well as help to address practical issues
such as insurance and opportunities for the child to continue
their education while under treatment. To further advance
health care provider and health system efforts to deliver optimal
care that integrates psychosocial and palliative care alongside
disease-directed treatment, several patient quality of lifefocused public policy initiatives are now under way involving a
coalition of patient advocacy and professional organizations.
For more information, see the Advocacy section on page 38.
Despite advances in treatment and survival for some cancers,
some children with cancer will not survive the disease. Although
patients, families, and health care providers often find it difficult to discuss issues concerning prognosis, goals of care, and
transitions to end-of-life care, it is important that health care
providers are available, attentive, and sensitive to these concerns.80,82 Pediatric oncology centers often partner with the
Common side effects of cancer treatment 80
• Low red blood cell counts (anemia) can result in pallor, dizziness, weakness, lack of energy, headache, and irritability. Low platelet
counts (thrombocytopenia) can result in easy bleeding and bruising. Low white blood cell counts (including low neutrophil counts
or neutropenia) reduce the body’s ability to fight infection. Low blood cell counts can be treated by transfusions or hematopoietic
growth factors, and risk of infection may be reduced by prophylactic antibiotics.
• Gastrointestinal side effects are common among children receiving chemotherapy or radiation therapy, and can include oral mucositis
(irritation and/or sores in the mouth), diarrhea or constipation, nausea, vomiting, and retching. Gastrointestinal side effects can result
in poor nutritional intake, leading to weight loss and delayed growth. Medications, such as antiemetics given before chemotherapy,
are available to reduce some of these side effects, and nutritional advice is available to help children and parents with these issues.
Nutritional support, such as tube feedings, intravenous feedings, or appetite stimulants, may be recommended.
• Pain may arise from the tumor as it presses on bone, nerves, or body organs; it can also result from procedures, including surgeries
and needle sticks. Pain can also be a side effect of some cancer treatment, such as neuropathic pain from some chemotherapy drugs.
Pain is often treatable by medication and other integrative non-medicine therapies. Children whose pain cannot be well-controlled
by available interventions should be seen by a specialist in pediatric pain management.
Cancer Facts & Figures 2014 37
family’s pediatrician and hospice professionals to provide care
to terminally ill children to manage pain and other symptoms,
help families to make informed decisions about the child’s care,
and support them through bereavement.83,84 The loss of a child
to cancer is an incredibly difficult experience. A variety of
resources (see page 39) are available for helping people through
their grieving process, including assistance in obtaining referrals for counseling and community-based support services.
cured with a 28-day course of low-dose cyclophosphamide and
prednisone and four intrathecal injections costing less than
$50.89 A number of organizations have drawn attention to the
survival disparity for retinoblastoma between high- and lowincome countries, and to the possibility that interventions such
as public awareness campaigns, physician education, hospital
partnerships, and donation of equipment could improve early
detection and treatment in low-income countries.90
Transition from Active Treatment to
Survivorship Care
What Is the American Cancer Society Doing
about Cancer in Children and Adolescents?
Children treated for cancer often maintain their relationship
with their primary care pediatrician. 85 Following cancer treatment, children and adolescents may be monitored by their
pediatric oncologist for 3 or more years, depending on the disease, age of the patient, and other factors. Follow-up care by
pediatric oncologists focuses on checking for recurrence; more
extensive follow-up may be offered by the treating oncologist or
by referral to a comprehensive clinic. When the time comes for
discontinuing visits to the pediatric oncologist for initial followup care, long-term follow-up care is still needed. Such follow-up
care includes assessment of short- and long-term complications
and late effects of cancer therapies; detection of recurrent and
secondary cancers; counseling about behaviors such as smoking, diet, and physical activity; assessment of psychosocial
adjustment and quality of life; and treatment for any identified
late effects.
Advocacy
Many of the late effects of childhood and adolescent cancer may
not become apparent until adulthood. Therefore, it is important
that young adults who are transitioning from pediatric to adult
primary care receive information regarding their cancer experience, including diagnosis and treatment, as well as follow-up
recommendations, especially if they are not participating in specialized survivorship care programs.85 The Children’s Oncology
Group (COG) has developed long-term follow-up guidelines for
survivors of childhood cancers.86 These guidelines help health
care providers and patients know what to watch for, what type of
screening tests should be done to look for problems, and how
late effects can be treated. For more information on these guidelines, visit the COG Web site at survivorshipguidelines.org.
Global Burden of Childhood Cancer
An estimated 175,000 cases of cancer are diagnosed annually in
children younger than 15 years of age worldwide, and fewer than
40% of patients (mostly in high-income countries) are adequately
diagnosed and treated.87 A child’s probability of surviving cancer is poor in less developed countries, and extreme discomfort
is likely in the absence of palliative care. Many childhood cancers are highly curable if diagnosed at an early stage, and some
treatment regimens are relatively simple, inexpensive, and wellestablished.88 For example, about 50% of African BL can be
38 Cancer Facts & Figures 2014
The Society’s nonprofit, nonpartisan advocacy affiliate, the
American Cancer Society Cancer Action Network SM (ACS CAN),
supports laws and policies that increase funding for cancer
research, improve the quality of life of all adults and children
with cancer and their families, and broaden access to quality
care.
A top and ongoing priority for ACS CAN is protecting and
increasing federal funding for cancer research at the National
Institutes of Health and the National Cancer Institute (NCI). NCI
funds about $200 million a year in research specific to childhood cancer. For more information, visit acscan.org/research
and ovaconline.org.
ACS CAN has worked with the Society to develop a menu of new
public policy proposals focused on increasing quality of life
(QOL) and scientific research on survivorship, boosting the
health care workforce, and improving access to quality health
care. In partnership with diverse stakeholders, ACS CAN is currently advancing federal and state legislation to promote pain
and symptom management and other aspects of palliative care
integrated with disease-directed treatment. These initiatives
include specific emphasis on addressing the quality-of-life needs
of children and adolescents who are facing cancer or other serious illness. For more information about this QOL campaign,
visit acscan.org/qualityoflife.
Moreover, for more than a decade, ACS CAN has worked on a
variety of childhood cancer public policies and legislative initiatives. Specifically, ACS CAN endorsed a number of bills, which
became law in 2012, that focus on pediatric cancer, including the
Reauthorization of the Best Pharmaceuticals for Children Act
(BPCA) and the Pediatric Research Equity Act (PREA). In addition, ACS CAN has endorsed the pediatric cancer community’s
legislative priorities for the 113th Congress, including the Childhood Cancer Survivors’ Quality of Life Act, and reauthorization
and appropriations for the Caroline Pryce Walker Conquer
Childhood Cancer Act.
ACS CAN is also an active participant in the Alliance for
Childhood Cancer — a coalition of more than 25 member organizations dedicated to advancing childhood cancer issues.
More information about the Alliance can be found at
allianceforchildhoodcancer.org/about.
cured without use of radiation to spare them the additional
side effects associated with radiation.
ACS CAN has successfully advocated for the inclusion of the following and other patient protections in the Affordable Care Act
that are vitally important to childhood and adolescent cancer
patients and survivors:
• Researchers at Yale University are comparing two survivorship models for children with cancer to improve long-term
outcomes and quality of life in these patients. Specifically,
the researchers are comparing the effectiveness of “survivorship clinics” to care provided by primary care physicians with
training in survivorship care.
• Protecting children and others from being dropped from
health insurance plans when they get sick
• Banning lifetime dollar caps on coverage and annual dollar
limits so that those with cancer get access to needed care
• Allowing families with children with life-threatening illnesses to enroll their children in hospice that is provided
concurrently with disease-directed treatment
• Enabling dependent children to remain on their parents’
health insurance policy up to age 26
Research
Resources for clinicians and parents
A detailed guide with additional information and resources on
cancer in children is available on the Society Web site:
cancer.org/cancer/cancerinchildren. This guide includes a listing of additional Society publications that may be downloaded
or ordered by calling our toll-free number, 1-800-227-2345.
Other national organizations and Web sites that provide information and support:
The American Cancer Society, through its Extramural Grants
program, funds individual investigators engaged in cancer
research or training at medical schools, universities, research
institutes, and hospitals throughout the US. As of September
2013, this program is funding approximately $29 million in
research specifically related to childhood and adolescent cancer
through 56 research grants. Additionally, the Society is funding
about $16 million in brain cancer research, $28 million in leukemia research, and $15 million in lymphoma research covering
both childhood and adult disease.
• American Childhood Cancer Organization: acco.org
Following are some examples of ongoing Society-funded childhood and adolescent cancer research projects:
1. Murphy SL, Xu J, Kochanek KD. Deaths: Final data for 2010. National
vital statistics reports; vol 61 no 4. Hyattsville, MD: National Center for
Health Statistics, 2013.
• Researchers at the University of Texas, Southwestern Medical Center are focused on what causes rhabdomyosarcoma.
They have discovered that many cases are associated with a
fusion of two genes. The team is currently conducting studies
to understand the consequences of this gene fusion, with
the goal of creating new therapies for this difficult-to-treat
cancer.
2. Steliarova-Foucher E, Stiller C, Lacour B, Kaatsch P. International
Classification of Childhood Cancer, third edition. Cancer. 2005;103:
1457-1467.
• Investigators from the University of Kansas Medical Center
are attempting to better understand metastasis in osteosarcoma. The investigators have discovered that a particular
regulatory protein, MTBP, can interfere with the primary
growth of osteosarcoma and its ability to metastasize to
distant sites. A better understanding of the molecular events
that promote metastases will provide the framework for
improved prevention and treatment.
5. Stiller CA, Parkin DM. Geographic and ethnic variations in the incidence of childhood cancer. Br Med Bull. 1996;52: 682-703.
• A research team at the Children’s Hospital of Los Angeles is
focused on trying to improve treatment of medulloblastoma.
Recent studies have shown that radiation treatment, when
added to surgery and chemotherapy, may not be necessary for
some children. The researchers are trying to develop a prognostic tool that would identify those children who might be
• Children’s Oncology Group (COG):
childrensoncologygroup.org
• CureSearch for Children’s Cancer: curesearch.org
• National Cancer Institute resources for childhood cancer:
cancer.gov/cancertopics/types/childhoodcancers
• National Children’s Cancer Society, Inc: thenccs.org
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childhood cancer: bridgeable gaps in scientific knowledge. Mutat Res.
2006;608: 136-156.
24. Landrigan PJ, Goldman LR. Children’s vulnerability to toxic chemicals: a challenge and opportunity to strengthen health and environmental policy. Health Aff (Millwood). 2011;30: 842-850.
25. Office on Women’s Health, US Department of Health and Human
Services. You’re pregnant: Now what? Environmental Risks. Available
from URL: http://womenshealth.gov/pregnancy/you-are-pregnant/
staying-healthy-safe.html Accessed November 6, 2013.
26. National Institute for Occupational Safety and Health. The Effects
of Workplace Hazards on Female Reproductive Health. Cincinnati, OH:
Department of Health and Human Services, 1999.
27. Dang-Tan T, Franco EL. Diagnosis delays in childhood cancer: a
review. Cancer. 2007;110: 703-713.
28. Margolin J, Rabin, KR, Steuber, CP and Poplack, DG. Acute Lymphoblastic Leukemia. In: Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins, 2010:518-565.
40 Cancer Facts & Figures 2014
34. Robison LL. Late effects of acute lymphoblastic leukemia therapy
in patients diagnosed at 0-20 years of age. Hematology Am Soc Hematol
Educ Program. 2011;2011: 238-242.
35. Eden T. Aetiology of childhood leukaemia. Cancer Treat Rev. 2010;36:
286-297.
36. Cooper TM, Hasle H, Smith FO. Acute Myeloid Leukemia, Myeloproliferative and Myelodysplastic Disorders. In: Pizzo PA, Poplack DG,
editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA:
Wolters Kluwer Health/Lippincott Williams & Wilkins, 2010:566-610.
37. Metzger M, Krasin MJ, Hudson MM, Onciu M. Hodgkin Lymphoma.
In: Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric
Oncology. Philadelphia, PA: Wolters Kluwer Health/Lippincott Williams
& Wilkins, 2010:638-662.
38. Swerdlow AJ, Cooke R, Bates A, et al. Breast cancer risk after supradiaphragmatic radiotherapy for Hodgkin’s lymphoma in England and
Wales: a National Cohort Study. J Clin Oncol. 2012;30: 2745-2752.
39. Travis LB, Hill DA, Dores GM, et al. Breast cancer following radiotherapy and chemotherapy among young women with Hodgkin disease.
JAMA. 2003;290: 465-475.
40. Saslow D, Boetes C, Burke W, et al. American Cancer Society guidelines for breast screening with MRI as an adjunct to mammography. CA
Cancer J Clin. 2007;57: 75-89.
41. Surveillance, Epidemiology and End Results (SEER) Program (www.
seer.cancer.gov) SEER*Stat Database: NAACCR Incidence – CiNA Analytic File, 1995-2010, for NHIAv2 Origin, Custom File With County, ACS
Facts and Figures Projection Project, North American Association of
Central Cancer Registries.
42. Gross TG, Perkins SL. Malignant Non-Hodgkin Lymphomas in Children. In: Pizzo PA, Poplack DG, editors. Principles and Practise of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer Health/Lippincott Williams & Wilkins, 2010:663-682.
43. Blaney SM, Haas-Kogan D, Poussaint Y, et al. Gliomas, Ependymomas, and Other Nonembryonal Tumors. In: Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA:
Wolters Kluwer Health/Lippincott Williams & Wilkins, 2010:717-771.
44. Packer RJ, Rorke-Adams LB, Lau CC, Taylor MD, Vezina G, Kun LE.
Embryonal and Pineal Tumors. In: Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer
Health/Lippincott Williams & Wilkins, 2010:772-808.
45. Black WC. Increasing incidence of childhood primary malignant
brain tumors – enigma or no-brainer? J Natl Cancer Inst. 1998;90: 12491251.
63. Mirabello L, Pfeiffer R, Murphy G, et al. Height at diagnosis and
birth-weight as risk factors for osteosarcoma. Cancer Causes Control.
2011;22: 899-908.
46. McKean-Cowdin R, Razavi P, Barrington-Trimis J, et al. Trends in
childhood brain tumor incidence, 1973-2009. J Neurooncol. 2013.
64. Kaste SC, Pratt CB, Cain AM, Jones-Wallace DJ, Rao BN. Metastases
detected at the time of diagnosis of primary pediatric extremity osteosarcoma at diagnosis: imaging features. Cancer. 1999;86: 1602-1608.
47. Baldwin RT, Preston-Martin S. Epidemiology of brain tumors in
childhood--a review. Toxicol Appl Pharmacol. 2004;199: 118-131.
65. Delatte O, Zucman J, Melot T, et al. The Ewing family of tumors-a
subgroup of small-round-cell tumors defined by specific chimeric transcripts. N Engl J Med. 1994;331:294-299.
48. Bunin GR, Gallagher PR, Rorke-Adams LB, Robison LL, Cnaan A.
Maternal supplement, micronutrient, and cured meat intake during
pregnancy and risk of medulloblastoma during childhood: a children’s
oncology group study. Cancer Epidemiol Biomarkers Prev. 2006;15: 16601667.
66. Hawkins DS, Bölling T, Dubois S, et al. Ewing Sarcoma. In: Pizzo PA,
Poplack DG, editors. Principles and Practice of Pediatric Oncology: Wolters Kluwer Health/Lippincott Williams & Wilkins, 2010:987-1011.
49. Pogoda JM, Preston-Martin S, Howe G, et al. An international casecontrol study of maternal diet during pregnancy and childhood brain
tumor risk: a histology-specific analysis by food group. Ann Epidemiol.
2009;19: 148-160.
67. Esiashvili N, Goodman M, Marcus RB, Jr. Changes in incidence and
survival of Ewing sarcoma patients over the past 3 decades: Surveillance
Epidemiology and End Results data. J Pediatr Hematol Oncol. 2008;30:
425-430.
50. Searles Nielsen S, Mueller BA, Preston-Martin S, Farin FM, Holly EA,
McKean-Cowdin R. Childhood brain tumors and maternal cured meat
consumption in pregnancy: differential effect by glutathione S-transferases. Cancer Epidemiol Biomarkers Prev. 2011;20: 2413-2419.
68. Ginsberg JP, Goodman P, Leisenring W, et al. Long-term survivors of
childhood Ewing sarcoma: report from the childhood cancer survivor
study. J Natl Cancer Inst. 2010;102: 1272-1283.
51. Warren KE. Diffuse intrinsic pontine glioma: poised for progress.
Front Oncol. 2012;2: 205.
52. Friedman DL, Kadan-Lottick NS, Whitton J, et al. Increased risk of
cancer among siblings of long-term childhood cancer survivors: a report
from the childhood cancer survivor study. Cancer Epidemiol Biomarkers
Prev. 2005;14: 1922-1927.
53. Brodeur GM, Hogarty MD, Mosse YP, Maris JM. Neuroblastoma. In:
Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer Health/Lippincott Williams &
Wilkins, 2010:886-922.
54. Nickerson HJ, Matthay KK, Seeger RC, et al. Favorable biology and
outcome of stage IV-S neuroblastoma with supportive care or minimal
therapy: a Children’s Cancer Group study. J Clin Oncol. 2000;18: 477-486.
55. Pietras W. Advances and changes in the treatment of children with
nephroblastoma. Adv Clin Exp Med. 2012;21: 809-820.
56. Narod SA, Hawkins MM, Robertson CM, Stiller CA. Congenital
anomalies and childhood cancer in Great Britain. Am J Hum Genet.
1997;60: 474-485.
57. Fernandez C, Geller JI, Ehrlich PF, et al. Renal Tumors. In: Pizzo PA,
Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, P.A.: Wolters Kluwer Health/Lippincott Williams & Wilkins,
2010:861-885.
58. Hurwitz RL, Shields CL, Shields JA, et al. Retinoblastoma. In: Pizzo
PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphis, PA: Wolters Kluwer Health/Lippincott Williams &
Wilkins, 2010:809-837.
59. Chintagumpala M, Chevez-Barrios P, Paysse EA, Plon SE, Hurwitz
R. Retinoblastoma: review of current management. Oncologist. 2007;12:
1237-1246.
60. Dimaras H, Kimani K, Dimba EA, et al. Retinoblastoma. Lancet.
2012;379: 1436-1446.
61. Kleinerman RA, Yu CL, Little MP, et al. Variation of second cancer
risk by family history of retinoblastoma among long-term survivors. J
Clin Oncol. 2012;30: 950-957.
62. Gorlick R, Bielack S, Teot L, Meyer J, Randall RL, Neyssa M. Osteosarcoma: Biology, Diagnosis, Treatment, and Remaining Challenges. In:
Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. philadelphia, PA: Wolters Kluwer Health/Lippincott Williams &
Wilkins, 2010:1015-1044.
69. Gurney JG, Young JL, Roffers SF, Smith MA, GR B. Soft tissue sarcomas. In: Ries LAG, Smith MA, Gurney JG, et al., editors. Cancer Incidence
and Survival among Children and Adolescents: United States SEER Program 1975-1995. Bethesda, MD: National Cancer Institute, SEER Program, 1999.
70. Wexler LH, Meyer WH, Helman LJ. Rhabdomyosarcoma. In: Pizzo
PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer Health/Lippincott Williams &
Wilkins, 2010:923-953.
71. Arndt CA, Rose PS, Folpe AL, Laack NN. Common musculoskeletal
tumors of childhood and adolescence. Mayo Clin Proc. 2012;87: 475-487.
72. Olson TA, Schneider DT, Perlman EJ. Germ Cell Tumors. In: Pizzo
PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology.
Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins,
2010:1045-1067.
73. De Backer A, Madern GC, Oosterhuis JW, Hakvoort-Cammel FG,
Hazebroek FW. Ovarian germ cell tumors in children: a clinical study of
66 patients. Pediatr Blood Cancer. 2006;46: 459-464.
74. Hastings CA, Torkildson JC, Agrawal AK. Chapter 21. Germ Cell
Tumors. Handbook of Pediatric Hematology and Oncology: Children’s
Hospital & Research Center, 2nd edition. West Sussex: John Wiley & Sons,
Ltd., 2012:193-199.
75. Cost NG, Lubahn JD, Adibi M, et al. A comparison of pediatric, adolescent, and adult testicular germ cell malignancy. Pediatr Blood Cancer.
2013.
76. Krane EJ, Casillas J, Zeltzer L. Pain and Symptom Management. In:
Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer Health/Lippincott Williams &
Wilkins, 2010:1256-1287.
77. Oppenheim D. The child’s subjective experience of cancer and the
relationship with parents and caregivers. In: Kreitler S, Ben Arush MW,
editors. Psychosocial Aspects of Pediatric Oncology. West Sussex, England: John Wiley and Sons, Ltd, 2004:109-138.
78. O’Shea ER, Bennett Kanarek R. Understanding pediatric palliative
care: what it is and what it should be. J Pediatr Oncol Nurs. 2013;30: 34-44.
79. Section On Hospice and Palliative Medicine and Committee On
Hospital Care. Pediatric palliative care and hospice care commitments,
guidelines, and recommendations. Pediatrics. 2013;132: 966-972.
80. Bryant R. Managing side effects of childhood cancer treatment. J
Pediatr Nurs. 2003;18: 113-125.
Cancer Facts & Figures 2014 41
81. Wiener LS, Hersh SP, Alderfer MA. Psychiatric and Psychosocial Support for the Child and Family. In: Pizzo PA, Poplack DG, editors. Principles and Practice of Pediatric Oncology. Philadelphia, PA: Wolters Kluwer
Health/Lippincott Williams & Wilkins, 2010:1322-1346.
82. Skeen JE, Wesbter ML. Speaking to children about serious matters.
In: Kreitler S, Ben Arush MW, editors. Psychosocial Aspects of Pediatric
Oncology. West Sussex, England: John Wiley and Sons, Ltd, 2004:281-312.
83. Wolfe J, Tournay A, Zeltzer L. Palliatve care for children with
advanced cancer. In: Kreitler S, Ben Arush MW, editors. Psychosocial
Aspects of Pediatric Oncology. West Sussex, England: John Wiley and
Sons, Ltd, 2004:45-70.
84. Postovsky S, Ben Arush MW. Care of a child dying of cancer. In: Kreitler S, Ben Arush MW, editors. Psychosocial Aspects of Pediatric Oncology. West Sussex, England: John Wiley and Sons, Ltd, 2004:93-107.
85. Henderson TO, Friedman DL, Meadows AT. Childhood cancer survivors: transition to adult-focused risk-based care. Pediatrics. 2010;126:
129-136.
42 Cancer Facts & Figures 2014
86. Children’s Oncology Group. Long-term follow-up guidelines for survivors of childhood, adolescent and young adult cancers, Version 3.0.
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87. American Cancer Society. Global Cancer Facts & Figures 2nd Edition.
Atlanta: American Cancer Society, 2011.
88. Ribeiro R, Pui CH. Treatment of acute lymphoblastic leukemia in
low- and middle-income countries: challenges and opportunities. Leuk
Lymphoma. 2008;49: 373-376.
89. Hesseling P, Molyneux E, Kamiza S, Israels T, Broadhead R. Endemic
Burkitt lymphoma: a 28-day treatment schedule with cyclophosphamide and intrathecal methotrexate. Ann Trop Paediatr. 2009;29: 29-34.
90. Dimaras H, Dimba EA, Gallie BL. Challenging the global retinoblastoma survival disparity through a collaborative research effort. Br J
Ophthalmol. 2010;94: 1415-1416.
Tobacco Use
Smoking-related diseases remain the world’s most preventable
cause of death. Since the first US Surgeon General’s report on
smoking and health in 1964, there have been more than 15 million premature deaths attributable to smoking in the US.1,2
Worldwide, 6 million people die annually from tobacco use; by
2030, the number will rise to 8 million deaths annually. 3, 4
Health Consequences of Smoking
Half of all those who continue to smoke will die from smokingrelated diseases.5 In the US, tobacco use is responsible for nearly
1 in 5 deaths; this equaled an estimated 443,000 premature
deaths each year between 2000 and 2004.6,7 In addition, an estimated 8.6 million people suffer from chronic conditions related
to smoking, such as chronic bronchitis, emphysema, and cardiovascular diseases.8
• Smoking accounts for at least 30% of all cancer deaths,
including 87% of lung cancer deaths among men and 70% of
lung cancer deaths among women.9
• The risk of developing lung cancer is about 23 times higher in
male smokers and 13 times higher in female smokers, compared to lifelong nonsmokers.1
• Smoking increases the risk of the following types of cancer:
nasopharynx, nasal cavity and paranasal sinuses, lip, oral
cavity, pharynx, larynx, lung, esophagus, pancreas, uterine
cervix, ovary (mucinous), kidney, bladder, stomach, colorectum, and acute myeloid leukemia.1,10
• The International Agency for Research on Cancer (IARC)
recently concluded that there is some evidence that tobacco
smoking causes female breast cancer.10
• Smoking is a major cause of heart disease, cerebrovascular
disease, chronic bronchitis, and emphysema, and is associated with gastric ulcers.1,11
• The risk of lung cancer is just as high in smokers of “light” or
“low-tar” yield cigarettes as in those who smoke “regular” or
“full-flavored” products.12
Reducing Tobacco Use and Exposure
In 2000, the US Surgeon General outlined the goals and components of comprehensive statewide tobacco control programs.13
These programs seek to prevent the initiation of tobacco use
among youth; promote quitting at all ages; eliminate nonsmokers’ exposure to secondhand smoke; and identify and eliminate
the disparities related to tobacco use and its effects among different population groups.14
The Centers for Disease Control and Prevention (CDC) recommends funding levels for comprehensive tobacco use prevention
and cessation programs for all 50 states and the District of
Columbia. In fiscal year 2013, 5 states allocated 50% or more of
CDC-recommended funding levels for tobacco control programs.15 States that have previously invested in comprehensive
tobacco control programs, such as California, Massachusetts,
and Florida, have reduced smoking rates and saved millions of
dollars in tobacco-related health care costs.13 Recent federal initiatives in tobacco control, including national legislation
ensuring coverage of some clinical cessation services, regulation of tobacco products, and tax increases, hold promise for
reducing tobacco use. Provisions in the Affordable Care Act
ensure at least minimum coverage of evidence-based cessation
treatments, including pharmacotherapy and cessation counseling, to previously uninsured tobacco users, pregnant Medicaid
recipients, and eligible Medicare recipients. The Centers for
Medicare and Medicaid Services subsequently issued a decision
memo changing the eligibility requirement for Medicare recipients, so that they no longer have to be diagnosed with a
smoking-related disease in order to access cessation treatments.
Starting in 2014, state Medicaid programs can no longer exempt
cessation pharmacotherapy from prescription drug coverage.
Several provisions of the Family Smoking Prevention and
Tobacco Control Act, which for the first time grants the US Food
and Drug Administration the authority to regulate the manufacturing, selling, and marketing of tobacco products, have
already gone into effect. For more information about tobacco
control, see Cancer Prevention & Early Detection Facts & Figures,
available online at cancer.org/statistics.
Cigarette Smoking
Between 1965 and 2004, cigarette smoking among adults 18
years of age and older declined by half from 42% to 21%.16
Between 2005 and 2012, there was a modest, but statistically significant, decline in smoking prevalence from 21% to 18%, though
declines were not consistent from year to year and were not
observed in all population subgroups. 17-19
• In 2011, approximately 41.5 million adults were current smokers, about 4 million fewer than in 2005.
• The proportion of daily smokers reporting light or intermittent smoking (less than 10 cigarettes per day) increased
significantly between 2005 (16%) and 2012 (21%), whereas
heavy smoking declined from 13% to 7%.17-19
• Although cigarette smoking became prevalent among men
before women, the gender gap narrowed in the mid-1980s
and has since remained constant.20 As of 2012, there was a 2
percentage point difference in smoking prevalence between
white men (21%) and women (19%), a 7 percentage point difference between African American men (22%) and women
Cancer Facts & Figures 2014 43
(15%), a 9 percentage point difference between Hispanic men
(17%) and women (8%), and a 12 percentage point difference
between Asian men (17%) and women (5%).19
• Smoking is most common among the least educated. For
example, in 2012, smoking prevalence was 32% among adults
with 9-11 years of education and 6% among those with graduate degrees.19 The highest smoking rate was among adults
with a GED (General Educational Development), or high
school equivalency credential (42%).
• While the percentage of smokers has decreased at every level
of educational attainment, college graduates have had the
greatest decline, from 21% in 1983 to 9% in 2012.18,19,21 Among
those with a high school diploma, prevalence decreased less
dramatically, from 34% to 23%.
• Among US states in 2012, the prevalence of adult smoking
ranged from 10.6% in Utah to 28.3% in Kentucky.22
• The decrease in smoking prevalence among high school
students between the late 1970s and early 1990s was more
rapid among African Americans than whites; consequently,
lung cancer rates among adults younger than 40 years of
age, which historically were substantially higher in African
Americans, have converged.23
• Smokers who use smokeless products as a supplemental
source of nicotine to postpone or avoid quitting will increase
rather than decrease their risk of lung cancer. 32
• Long-term use of snuff substantially increases the risk of
cancers of the oral cavity, particularly cancers of the cheek
and gum.31
• According to the US Department of Agriculture, manufactured output of moist snuff has increased more than 80% in
less than two decades, from 48 million pounds in 1991 to an
estimated 88 million pounds in 2007. 33,34
• According to the 2012 National Health Interview Survey, 11%
of adults 18 years of age and older (20% of men and 3% of
women) have ever used smokeless products.19
• According to the 2012 National Survey on Drug Use and
Health (NSDUH), whites and American Indians/Alaska
Natives were more likely to use smokeless tobacco than African Americans, Hispanics/Latinos, or Asians. 35
• Adult smokeless tobacco use (including snus use) varied from
1% to 9% across states in 2012, with higher rates observed in
the South and North-Central states.22
• Although cigarette smoking among US high school students
increased from 28% in 1991 to 36% in 1997, it had declined to
14% by 2012.24-26
• Smokeless tobacco use among high school boys decreased
consistently between 1986 and 2003 (from 19% to 11%),
but has since remained fairly level (13% in 2011 and 11% in
2012).26,27 Use among girls has been low and stable (from 1%
in 1986 to 2% in 2003, 2011, and 2012).
Smokeless Tobacco Products
Cigars
Smokeless tobacco products include moist snuff, chewing
tobacco, snus (a “spitless,” moist powder tobacco pouch), dissolvable nicotine products (e.g., Camel Orbs, Camel Strips, and
Camel Sticks), and a variety of other tobacco-containing products that are not smoked. Recently, the smokeless market in
high-income countries, including the US, has been consolidated
from smaller tobacco companies into the control of tobacco
multinational corporations.4 In the US, the sales of smokeless
tobacco products are growing at a more rapid pace than cigarettes. As part of their marketing strategy, the industry is actively
promoting these products both for use in settings where smoking is prohibited and as a way to quit smoking; however, there is
no evidence to date that these products are as effective as proven
cessation therapies for quitting. When smokeless tobacco was
aggressively marketed in the US in the 1970s and 1980s, use of
these products increased among adolescent males, but not
among older smokers trying to quit.28,29 Use of any smokeless
tobacco product is not considered a safe substitute for quitting.
These products cause oral, esophageal, and pancreatic cancers,
precancerous lesions of the mouth, gum recession, bone loss
around the teeth, and tooth staining; they can also lead to nicotine addiction.30,31
Cigar smoking has health consequences similar to those of cigarette smoking and smokeless tobacco.36 Historically, lower tax
rates on cigars have caused some smokers to switch from cigarettes to less costly cigars. While total cigarette consumption
declined by 33% from 2000 to 2011, large cigar consumption
(including cigarillos) increased by 233%.37
44 Cancer Facts & Figures 2014
• Regular cigar smoking is associated with an increased risk
of cancers of the lung, oral cavity, larynx, esophagus, and
probably pancreas. Cigar smokers have 4 to 10 times the risk
of dying from laryngeal, oral, or esophageal cancer compared
to nonsmokers. 36
• In 2012, 5% of adults 18 years of age and older (9% of men and
2% of women) were current cigar smokers (at least once in the
past month).35
• According to the 2012 NSDUH, African Americans had the
highest prevalence of cigar use, followed by American Indians/Alaska Natives, whites, Hispanics, and Asians. 35
• In 2011, 13% of US high school students had smoked cigars,
cigarillos, or little cigars at least once in the past 30 days
down from 22% in 1997.26
• Cigars are taxed based on weight, and large cigars are taxed
at a lower rate than small cigars and manufactured ciga-
Annual Number of Cancer Deaths Attributable to Smoking by Sex and Site, US, 2000-2004
Male
Female
Oral cavity & pharynx
Oral cavity & pharynx
Larynx
Larynx
Cancer site
Pancreas
Lung
Cancer site
Stomach
Stomach
Pancreas
Lung
Bladder
Bladder
Kidney
Kidney
Myeloid leukemia
Myeloid leukemia
20
Other causes
Esophagus
Esophagus
0
Attributable to
cigarette smoking
40
60
80
Number of deaths (in thousands)
Cervix
100
0
20
40
60
80
Number of deaths (in thousands)
100
Source: Centers for Disease Control and Prevention. Smoking-attributable mortality, years of potential life lost, and productivity losses – United States, 2000-2004.
MMWR Morb Mortal Wkly Rep. 2008;57(45):1226-1228.
American Cancer Society, Surveillance Research, 2014
rettes.38 Manufacturers are taking advantage of the tax break
for large cigars by slightly increasing the weight of small
cigars in order to lower cost while maintaining the appeal of
the smaller size.35
Smoking Cessation
A US Surgeon General’s Report outlined the benefits of smoking
cessation: 39
least one day during the preceding 12 months because they
were trying to quit.19
• In 2011, among high school students who were current
cigarette smokers, national data showed that one-half (50%)
had tried to quit smoking cigarettes during the 12 months
preceding the survey; female students (54%) were more likely
to have made a quit attempt than male students (47%).26
• Quitting smoking substantially decreases the risk of lung,
laryngeal, esophageal, oral, pancreatic, bladder, and cervical
cancers.
Effective cessation treatments can double or triple a smoker’s
chances of long-term abstinence.41 Certain racial and ethnic
groups (Hispanics and non-Hispanic African Americans) and
those with low socioeconomic status are significantly less likely
to receive cessation services.42 One way to help reduce these
disparities is by increasing insurance coverage and promoting
available coverage for these treatments through government
health programs, including Medicaid and Medicare, and private
health insurance mandates.
• Quitting lowers the risk for other major diseases, including
heart disease, chronic lung disease, and stroke.
Secondhand Smoke
• People who quit, regardless of age, live longer and are healthier than people who continue to smoke.
• Smokers who quit before age 50 cut their risk of dying in the
next 15 years in half.
• While the majority of ever-smokers in the US have quit
smoking, rates of adult smoking cessation remained stable
between 1998 and 2008.40
• In 2012, an estimated 51.5 million adults were former smokers, representing 55% of living persons who ever smoked.19
• In fact, in all 50 states and the District of Columbia, the
majority of adults who have ever smoked have now quit.22
• Smokers with an undergraduate or graduate degree are more
likely to quit than less educated smokers.40 Among those who
smoked in 2012, approximately 51% had stopped smoking at
In 2006, the US Surgeon General published a comprehensive
report titled The Health Consequences of Involuntary Exposure to
Tobacco Smoke.43 This report determined that secondhand
smoke (SHS), or environmental tobacco smoke, contains numerous human carcinogens for which there is no safe level of
exposure. It is estimated that more than 88 million nonsmoking
Americans 3 years of age and older were exposed to SHS in 20072008.44 Numerous other scientific consensus groups have also
reviewed data on the health effects of SHS.43-49 Public policies to
protect people from SHS are based on the following detrimental
effects:
Cancer Facts & Figures 2014 45
• SHS contains more than 7,000 chemicals, at least 69 of which
cause cancer.2
• Each year, about 3,400 nonsmoking adults die of lung cancer
as a result of breathing SHS.6
• SHS causes an estimated 42,000 deaths annually from heart
disease in people who are not current smokers. 50
• SHS may cause coughing, wheezing, chest tightness, and
reduced lung function in adult nonsmokers.44
• Some studies have reported an association between SHS
exposure and breast cancer. In 2006, the US Surgeon General
designated this evidence as suggestive rather than conclusive, while a subsequent meta-analysis concluded that there
was no association between secondhand smoke and breast
cancer.43,51 In any case, women should be aware that there are
many health reasons to avoid exposure to tobacco smoke.
Laws that prohibit smoking in public places and create smokefree environments are the most effective approach to prevent
exposure to and harm from SHS.52 In addition, there is strong
evidence that smoke-free policies decrease the prevalence of
both adult and youth smoking.52 Momentum to regulate public
smoking began to increase in 1990, and smoke-free laws have
become increasingly common and comprehensive over time. 53
• In the past decade, the largest decline in SHS exposure
among nonsmokers occurred from 1999-2000 (53%) to
2001-2002 (42%), with estimates since remaining relatively
unchanged (2007-2008: 40%).43
• In the US, as of July 8, 2013, 575 municipalities and 24 states,
the District of Columbia, the Northern Mariana Islands,
Puerto Rico, American Samoa, and the US Virgin Islands
have laws in place requiring all non-hospitality workplaces,
restaurants, and bars to be 100% smoke-free.54
• In the US, as of July 8, 2013, there were 1,182 100% smoke-free
college campuses; of these, 798 are 100% tobacco-free (i.e., no
forms of tobacco allowed).54
• Currently, 49% of the US population is covered by a 100%
smoke-free policy in workplaces, restaurants, and bars. 54
Workplace smoking restrictions vary by geographic area; 72% of
Southern residents reported working under a smoke-free policy,
compared to 81% of workers in the Northeast. 55
Costs of Tobacco
The number of people who die prematurely or suffer illness from
tobacco use impose substantial health-related economic costs
on society. It is estimated that in the US, between 2000 and 2004,
smoking accounted for 3.1 million years of potential life lost in
men and 2.0 million years of potential life lost in women. Smoking, on average, reduces an individual’s life expectancy by
approximately 14 years.6
46 Cancer Facts & Figures 2014
In addition:
• Between 2000 and 2004, smoking resulted in more than $193
billion in average annual health-related costs, including $96
billion in smoking-attributable medical costs and $97 billion
in productivity losses.6
• From 1997-2001 to 2000-2004, smoking-attributable health
care expenditures were estimated to increase $24 billion
annually, while smoking-attributable productivity losses
increased $4.3 billion annually.6,56
Conclusion
Substantial progress has been made in reducing the disease burden from tobacco over the nearly 50 years since the first report
of the Surgeon General’s Advisory Committee on Smoking and
Health. Smoking prevalence has been reduced by more than half
and millions of premature deaths have been averted. Nevertheless, more needs to be done to further reduce the health and
economic burden of tobacco. Numerous studies confirm that a
comprehensive approach to tobacco control, including higher
taxes, 100% smoke-free environments, coverage for tobacco
dependence treatment, full implementation of the FDA Family
Smoking Prevention and Tobacco Control Act, and vigorous
tobacco counter-advertising, can be successful in reducing the
death, disease, and economic disruption from tobacco use.
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Cancer Facts & Figures 2014 47
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Cancer Disparities
An overarching objective of the American Cancer Society’s 2015
challenge goals is to eliminate disparities in the cancer burden
among different segments of the US population, defined in terms
of socioeconomic status (income, education, insurance status,
etc.), race/ethnicity, geographic location, sex, and sexual orientation. The causes of health disparities within each of these
groups are complex and include interrelated social, economic,
cultural, environmental, and health system factors. However,
disparities predominantly arise from inequities in work, wealth,
education, housing, and overall standard of living, as well as
social barriers to high-quality cancer prevention, early detection, and treatment services.
Socioeconomic Status
People with lower socioeconomic status (SES) have disproportionately higher cancer death rates than those with higher SES,
regardless of demographic factors such as race/ethnicity. For
example, cancer mortality rates among both African American
48 Cancer Facts & Figures 2014
and non-Hispanic white men with 12 or fewer years of education
are almost 3 times higher than those of college graduates for all
cancers combined, and are 4-5 times higher for lung cancer. Furthermore, progress in reducing cancer death rates has been
slower in people with lower SES. These disparities occur largely
because people with lower SES are at higher risk for cancer and
have less favorable outcomes after diagnosis. People with lower
SES are more likely to engage in behaviors that increase cancer
risk, such as tobacco use, physical inactivity, and poor diet. This
is in part because of marketing strategies that target these populations, but also because of environmental or community
factors that provide fewer opportunities for physical activity
and less access to fresh fruits and vegetables. Lower SES is also
associated with financial, structural, and personal barriers to
health care, including inadequate health insurance, reduced
access to recommended preventive care and treatment services,
and lower literacy rates. Individuals with no health insurance
are more likely to be diagnosed with advanced cancer and less
likely to receive standard treatment and survive their disease.
For example, stage II colorectal cancer patients with private
insurance have better survival than stage I patients who are
uninsured. For more information about the relationship between
SES and cancer, see Cancer Facts & Figures 2011, Special Section,
and Cancer Facts & Figures 2008, Special Section, available
online at cancer.org.
Racial and Ethnic Minorities
Disparities in the cancer burden among racial and ethnic minorities largely reflect obstacles to receiving health care services
related to cancer prevention, early detection, and high-quality
treatment, with poverty as the overriding factor. According to
the US Census Bureau, in 2011, 28% of African Americans and
25% of Hispanics/Latinos lived below the poverty line, compared
to 10% of non-Hispanic whites. Moreover, 20% of African Americans and 30% of Hispanics/Latinos were uninsured, compared
to 11% of non-Hispanic whites.
Discrimination is another factor that contributes to racial/ethnic disparities in cancer mortality. Racial and ethnic minorities
tend to receive lower-quality health care than whites even when
insurance status, age, severity of disease, and health status are
comparable. Social inequalities, including communication barriers and provider assumptions, can affect interactions between
patient and physician and contribute to miscommunication or
delivery of substandard care.
In addition to poverty and social discrimination, cancer occurrence in a population may also be influenced by cultural and/or
inherited factors that decrease or increase risk. For example,
Hispanic women have a lower risk of breast cancer, in part,
because they tend to begin having children at a younger age,
which decreases breast cancer risk. Individuals who maintain a
primarily plant-based diet or do not use tobacco because of cultural or religious beliefs have a lower risk of many cancers.
Populations that include a large number of recent immigrants,
such as Hispanics and Asians, have higher rates of cancers
related to infectious agents (e.g., stomach, liver, uterine cervix),
reflecting a higher prevalence of infection in immigrant countries of origin. Genetic factors may also explain some differences
in cancer incidence. For example, women from population
groups with a higher frequency of mutations in the breast cancer susceptibility genes BRCA1 and BRCA2, such as women of
Ashkenazi Jewish descent, have an increased risk of breast and
ovarian cancer. Genetic factors may also play a role in the elevated risk of prostate cancer among African American men and
the incidence of more aggressive forms of breast cancer in African American women. However, genetic differences associated
with race or ethnicity make only a minor contribution to the disparate cancer burden between populations. Following is a brief
overview of the cancer burden for each of the four major nonwhite racial/ethnic groups.
African Americans: African Americans are more likely to
develop and die from cancer than any other racial or ethnic
group. Compared to non-Hispanic whites, the death rate for cancer among African Americans is 27% higher among men and
11% higher among women. With the exception of kidney cancer
mortality, African American men have higher incidence and
death rates than non-Hispanic whites for each of the cancer sites
listed in the table on page 51. The largest disparity is stomach
cancer, for which death rates are 2½-fold higher in African
Americans than in non-Hispanic whites among both men and
women. In addition, African Americans have double the death
rates of non-Hispanic whites for both cervical and prostate cancers. Notably, although African American women have a lower
breast cancer incidence rate than non-Hispanic white women,
their breast cancer death rate is higher. For more information on
cancer in African Americans, see Cancer Facts & Figures for African Americans, available online at cancer.org/statistics.
Hispanics: Hispanics have the lowest lung cancer incidence and
mortality rates of any major racial/ethnic group. However, they
have among the highest rates for cancers associated with infection, such as liver, stomach, and uterine cervix. For example,
cervical cancer incidence rates among Hispanic women are the
highest of any major minority population, and are 50% higher
than those among non-Hispanic whites. Incidence rates of liver
cancer and stomach cancers are about twice as high in Hispanics as in non-Hispanic whites. Higher prevalence of infection
with human papillomavirus (cervical cancer), hepatitis B virus
(liver cancer), and the bacterium H. pylori (stomach cancer) in
immigrant countries of origin contributes to these disparities.
For more information on cancer in Hispanics, see Cancer Facts &
Figures for Hispanics/Latinos, available online at cancer.org/
statistics.
Asian Americans and Pacific Islanders: Compared to other
racial/ethnic groups, Asian Americans and Pacific Islanders
(APIs) have the lowest overall cancer incidence and mortality
rates, as shown in the table on page 51. However, similar to Hispanics, this population has among the highest rates for cancers
of the liver and stomach due to a higher prevalence of infections
with hepatitis B virus and H. pylori, respectively. Liver cancer
incidence rates among APIs are about 2½-fold higher than those
among non-Hispanic whites, while death rates are double. In
contrast to Hispanics, APIs have the lowest cervical cancer incidence and mortality rates of all major racial/ethnic groups.
American Indians and Alaska Natives: American Indians and
Alaska Natives (AIANs) have the highest kidney cancer incidence and death rates by far of any other racial or ethnic
population – three times higher than those among APIs and 50%
higher than those among the remaining subpopulations listed
in the table (page 51). A high prevalence of smoking and obesity
likely contributes to this disparity. Cancer information for
American Indians and Alaska Natives is known to be incomplete
because the racial/ethnic status of many of these individuals is
Cancer Facts & Figures 2014 49
not correctly identified in medical and death records. Although
efforts have been made to collect more accurate information
through linkage with the Indian Health Service records, available statistics probably do not represent the true cancer burden
in this population.
·· Improving the affordability of coverage by increasing
insurance subsidies and eliminating arbitrary annual and
lifetime caps on coverage for all insurance plans so that
families affected by cancer will face fewer financial barriers to care
Note: It is important to recognize that although cancer data in
the US are primarily reported for broad racial and ethnic minority groups, these populations are not homogenous. There are
significant variations in the cancer burden within each racial/
ethnic group. For example, among Asian Americans, incidence
rates for cervical cancer are almost three times higher in Vietnamese women than in Chinese and Japanese women, partly
because the Vietnamese, in general, immigrated more recently
and are poorer, with less access to cervical cancer screening.
·· Focusing on prevention and early detection by requiring
all new insurance plans to provide coverage for essential,
evidence-based preventive measures with no additional
copays
Geographic Variability
Cancer rates in the US vary by geographic area, with larger differences for some cancer sites than others. Lung cancer, for
example, shows the most striking variation by state (figure, page
52). Lung cancer death rates are more than 3-fold higher in
Kentucky (97 and 56 per 100,000 in men and women, respectively) – the state with the highest rates – than in Utah (28 and 17
per 100,000 in men and women, respectively), which has the lowest rates. These differences reflect the substantial historic and
continuing variation in smoking prevalence among states,
which is influenced to some extent by state tobacco control policies. Geographic variations in cancer occurrence also reflect
differences in environmental exposures, socioeconomic factors
related to population demographics, and screening behaviors.
For more information about cancer disparities, see Cancer Facts
& Figures 2011, Special Section, available online at cancer.org.
Public Policy
The American Cancer Society and the American Cancer Society
Cancer Action Network SM (ACS CAN), the Society’s nonprofit,
nonpartisan advocacy affiliate, are dedicated to reducing cancer incidence and mortality rates among minority and medically
underserved populations. This goal can be achieved by instituting effective policies and public health programs that promote
overall wellness and help save lives. Listed below are some of the
efforts at both the state and federal levels that the Society and
ACS CAN have been involved with in the past few years:
• Patient Protection and Affordable Care Act. The Society
and ACS CAN are working to ensure that key provisions of
the Affordable Care Act (ACA) that benefit cancer patients
and survivors are implemented as strongly as possible and
are adequately funded. Some of the law’s provisions that will
directly help address disparities include:
50 Cancer Facts & Figures 2014
·· Eliminating discrimination based on health status and
preexisting conditions, which has been so detrimental to
cancer patients over the years
·· Requiring qualified health plans to provide materials in
appropriate languages
ACS CAN will continue to look for ways to strengthen the legislation throughout the implementation process both at the federal
and state level.
• National Breast and Cervical Cancer Early Detection
Program. A high priority for the Society and ACS CAN at
both the state and federal level is fighting to increase funding
for the National Breast and Cervical Cancer Early Detection Program (NBCCEDP). This successful program, which
began in 1991, provides community-based breast and cervical
cancer screening to low-income, uninsured, and underinsured women, more than 50% of whom are from racial/ethnic
minority groups. Due to a large cut in funding, screening
rates within the program greatly declined in 2007; rates have
been increasing slowly since, but still have not fully recovered. ACS CAN is asking Congress to protect funding for
fiscal year 2014 to support continued need and to give women
access to lifesaving screening services. While the Affordable
Care Act will greatly improve access to screening, the NBCCEDP will remain an essential program for improving breast
and cervical cancer screening and treatment in our nation’s
most vulnerable populations. It will be critical to use the program’s infrastructure and community-outreach specialists to
help women receive the lifesaving services they need.
• Patient Navigation. Patient navigation demonstration
programs show that navigation is an important aspect of
improving satisfaction and care among cancer patients,
especially those in medically underserved and minority
populations. In order to increase patient navigation services,
ACS CAN is looking to expand the reach of patient navigators
through federal funding support.
The Society and ACS CAN also are leading efforts to increase
federal investment in cutting-edge biomedical and cancer
research and treatments, as well as ways to expand access to
them. To learn more, to get involved, and to make a difference in
the fight against cancer, visit cancer.org/involved/advocate.
Cancer Incidence and Death Rates* by Site, Race, and Ethnicity, US, 2006-2010
Incidence Non-Hispanic
White
African
American
Asian American
or Pacific Islander
American Indian
or Alaska Native†
Hispanic/
Latino
All sites
Male
Female
548.6
436.2
601.0
395.9
326.1
282.6
441.1
372.0
426.8
330.8
Breast (female)
127.3
118.4
84.7
90.3
91.1
Colon & rectum
Male
Female
50.9
38.6
62.5
46.7
40.8
31.0
51.7
42.7
47.3
32.6
Kidney & renal pelvis
Male
Female
21.6
11.2
23.0
12.2
10.6
5.1
30.6
17.5
20.5
11.5
8.7
2.9
14.9
4.4
21.3
8.0
17.8
8.0
18.8
6.9
82.9
59.9
94.7
50.4
48.8
28.0
70.2
52.1
45.9
26.6
Liver & intrahepatic bile duct
Male
Female
Lung & bronchus
Male
Female
Prostate
138.6220.0
Stomach
Male
Female
7.8
3.5
15.7
8.1
Uterine cervix
7.2
10.3
75.0
104.1
124.2
15.6
9.0
13.1
6.9
13.9
8.2
6.7
9.7
10.9
Mortality All sites
Male
Female
217.3
153.6
276.6
171.2
132.4
92.1
191.0
139.0
152.1
101.2
Breast (female)
22.7
30.8
11.5
15.5
14.8
Colon & rectum
Male
Female
19.2
13.6
28.7
19.0
13.1
9.7
18.7
15.4
16.1
10.2
Kidney & renal pelvis
Male
Female
5.9
2.6
5.7
2.6
3.0
1.2
9.5
4.4
5.1
2.3
Liver & intrahepatic bile duct
Male
Female
7.1
2.9
11.8
4.1
14.4
6.0
13.2
6.1
12.3
5.4
Lung & bronchus
Male
Female
65.7
42.7
78.5
37.2
35.5
18.4
49.6
33.1
31.3
14.1
Prostate
21.350.9 10.1
20.7
19.2
Stomach
Male
Female
3.9
1.9
9.8
4.7
8.7
5.1
8.1
3.8
7.6
4.4
Uterine cervix
2.1
4.2
1.9
3.5
2.9
Hispanic origin is not mutually exclusive from African American, Asian American/Pacific Islander, or American Indian/Alaska Native.
*Rates are per 100,000 population and age adjusted to the 2000 US standard population. † Data based on Indian Health Service Contract Health Service Delivery Areas.
‡Mortality rates for Hispanics and non-Hispanic whites exclude deaths from the District of Columbia, North Dakota, and South Carolina. Source: Incidence - North
American Association of Central Cancer Registries.
Source: Incidence - North American Association of Central Cancer Registries, 2013. US Mortality Data - National Center for Health Statistics Centers for Disease Control and
Prevention.
American Cancer Society, Surveillance Research, 2014
Cancer Facts & Figures 2014 51
Geographic Patterns in Lung Cancer Death Rates* by State, US, 2006-2010
Males
WA
MT
ND
ME
MN
OR
ID
VT
NH
SD
WI
NY
WY
MI
IA
NE
NV
IL
AZ
MO
50.0 - 59.7
NC
59.8 - 69.9
SC
MS
TX
27.5 - 49.9
DC
KY
AR
NM
Rate per 100,000 males
MD
VA
TN
OK
AK
DE
WV
KS
NJ
OH
IN
CO
CA
RI
CT
PA
UT
MA
AL
70.0 - 84.3
84.4 - 97.1
GA
LA
FL
HI
Females
WA
MT
ND
ME
MN
OR
ID
VT
NH
SD
WI
NY
WY
MI
IA
NE
NV
PA
UT
IL
IN
OH
CO
CA
KS
AZ
MO
OK
NM
TX
NC
TN
SC
MS
AK
VA
KY
AR
AL
RI
CT
NJ
DE
WV
MA
MD
DC
Rate per 100,000 females
16.8 - 25.8
25.9 - 36.1
36.2 - 40.8
40.9 - 45.3
45.4 - 55.8
GA
LA
FL
HI
*Rates adjusted to the 2000 US standard population.
Source: US Mortality Data, National Center for Health Statistics, Centers for Disease Control and Prevention.
American Cancer Society, Surveillance Research, 2014
52 Cancer Facts & Figures 2014
Nutrition and Physical Activity
It has been estimated by the World Cancer Research Fund that
one-quarter to one-third of the cancers that occur in highincome countries like the US are due to poor nutrition, physical
inactivity, and excess weight, and thus could be prevented.
Maintaining a healthy body weight, being physically active on a
regular basis, and eating a healthy diet are as important as
avoiding tobacco products for reducing cancer risk. The American Cancer Society’s nutrition and physical activity guidelines
emphasize the importance of weight control, physical activity,
healthy dietary patterns, and limited, if any, alcohol consumption in reducing cancer risk and helping people stay well.
Unfortunately, the majority of Americans are not meeting these
recommendations. Increasing trends in unhealthy eating and
physical inactivity – and resultant increases in overweight and
obesity – have largely been influenced by the environments in
which people live, learn, work, and play. As a result, the Society’s
guidelines include explicit Recommendations for Community
Action to facilitate the availability of healthy, affordable food
choices and opportunities for physical activity in communities,
schools, and workplaces.
The following recommendations reflect the best nutrition and
physical activity evidence available to help Americans reduce
their risk of cancer and promote overall health.
Recommendations for Individual Choices
1. Achieve and maintain a healthy weight
throughout life.
• Be as lean as possible throughout life without being
underweight.
• Avoid excess weight gain at all ages. For those who are currently overweight or obese, losing even a small amount of
weight has health benefits and is a good place to start.
• Engage in regular physical activity and limit consumption of
high-calorie foods and beverages as key strategies for maintaining a healthy weight.
In 2003, overweight and obesity were found to contribute to 14%
to 20% of all cancer-related mortality; however, because this
estimate was based on weight patterns during 1999-2000, the
fraction is probably larger today. Overweight and obesity are
clearly associated with increased risk for developing many cancers, including adenocarcinoma of the esophagus and cancers of
the breast (in postmenopausal women), colon, rectum, endometrium, kidney, and pancreas. Overweight and obesity may also
be associated with an increased risk of aggressive prostate cancer, non-Hodgkin lymphoma, multiple myeloma, and cancers of
the liver, cervix, ovary, and gallbladder. Abdominal fatness in
particular is convincingly associated with colorectal cancer,
and probably related to higher risk of pancreatic and endometrial cancers.
Increasing evidence also suggests that being overweight
increases the risk for cancer recurrence and decreases the likelihood of survival for several cancers. Some studies have shown
that surgery to treat morbid obesity reduces mortality from
major chronic diseases, including cancer. Although knowledge
about the relationship between weight loss and cancer risk is
incomplete, individuals who are overweight should be encouraged and supported in their efforts to reduce weight.
At the same time that evidence connecting excess weight to
increased cancer risk has been accumulating, trends in overweight and obesity have been increasing dramatically. The
prevalence of obesity in the US more than doubled between
1976-1980 and 2003-2006. Although obesity levels have stabilized in recent years, more than one-third of adults – 36% of both
men and women – were obese in 2009-2010. More than likely,
these trends are already impacting cancer rates: in the midpoint
assessment of its 2015 Challenge Goals, American Cancer Society researchers reported that while the incidence of both
colorectal cancer and postmenopausal breast cancer had been
declining, it is likely that the declines in both would have started
earlier and would have been steeper had it not been for the
increasing prevalence of obesity. Indeed, some researchers have
speculated that the longstanding, historic increases in life
expectancy in the US may level off or even decline within the
first half of this century as a result of the obesity epidemic.
Similar to adults, obesity among children and adolescents has
tripled over the past several decades across race, ethnicity, and
gender. In 2009-2010, 17% of American children 2 to 19 years of
age were obese, including 24% of African Americans, 21% of Hispanics, and 14% of non-Hispanic whites. Because overweight in
youth tends to continue throughout life, efforts to establish
healthy body weight patterns should begin in childhood. The
high prevalence of overweight and obesity in children and adolescents may impact the future cancer burden. However, a recent
study of preschoolers enrolled in the Special Supplemental
Nutrition Program for Women, Infants, and Children conducted
by the Centers for Disease Control and Prevention (CDC) hinted
that the obesity epidemic may be stalling. Downturns in the
prevalence of obesity were observed among children 3 or 4 years
of age in New York City since 2003 and in Los Angeles since 2008.
Cancer Facts & Figures 2014 53
2. Adopt a physically active lifestyle.
• Adults should engage in at least 150 minutes of moderateintensity or 75 minutes of vigorous-intensity activity each
week, or an equivalent combination, preferably spread
throughout the week.
• Children and adolescents should engage in at least 1 hour
of moderate- or vigorous-intensity activity each day, with
vigorous-intensity activity at least three days each week.
• Limit sedentary behavior such as sitting, lying down,
and watching television and other forms of screen-based
entertainment.
• Doing any intentional physical activity above usual activities
can have many health benefits.
Living a physically active lifestyle helps reduce the risk of a variety of cancer types, as well as heart disease, diabetes, and many
other diseases. Scientific evidence indicates that physical activity may reduce the risk of cancers of the breast, colon, and
endometrium, as well as advanced prostate cancer. Physical
activity also indirectly reduces the risk of developing obesityrelated cancers because of its role in helping to maintain a
healthy weight. Being active is thought to reduce cancer risk
largely by improving energy metabolism and reducing circulating concentrations of estrogen, insulin, and insulin-like growth
factors. Physical activity also improves the quality of life of cancer patients and has been associated with reduced cancer
recurrence and overall mortality in multiple cancer survivor
groups, including breast, colorectal, prostate, and ovarian
cancer.
and foods are at a higher risk of developing or dying from a variety of cancers. Alternatively, adhering to a diet that contains a
variety of fruits and vegetables, whole grains, and fish or poultry
and fewer red and processed meats is associated with lower risk.
A recent study found that dietary and lifestyle behaviors consistent with the American Cancer Society nutrition and physical
activity guidelines are associated with lower mortality rates for
all causes of death combined, and for cancer and cardiovascular
diseases specifically. Despite the known benefits of a healthy
diet, Americans are not following recommendations; according
to the US Department of Agriculture, the majority of Americans
would need to substantially lower their intake of added sugars,
added fats, refined grains, and sodium, and increase their consumption of fruits, vegetables, whole grains, and low-fat dairy
products in order to meet the 2010 Dietary Guidelines for
Americans.
Currently, the overall evidence related to dietary supplements
does not support their use in cancer prevention. The results of
recently completed randomized clinical trials of antioxidant
supplements and selenium, which showed no reduction in risk
for cancer, at least in generally well-nourished populations, joins
the ranks of other nutritional supplements (such as beta-carotene) for which no benefit in cancer prevention has been shown.
Because it is likely that healthful components in fruits and vegetables work synergistically to exert beneficial effects, it is
recommended that nutritional needs be met primarily through
food sources.
Despite the wide variety of health benefits from being active,
25% of adults report no leisure-time activity, and only 49% meet
minimum recommendations for moderate activity. Similarly,
only 37% of youth meet recommendations. However, recent data
released by the CDC indicate that trends may be slightly improving. Walking prevalence (defined as walking for transportation
or leisure in at least one bout of 10 minutes or more in the preceding 7 days) among adults increased significantly from 56% in
2005 to 62% in 2010.
The scientific study of nutrition and cancer is highly complex,
and many important questions remain unanswered. It is not
presently clear how single nutrients, combinations of nutrients,
over-nutrition, and energy imbalance, or the amount and distribution of body fat at particular stages of life, affect a person’s risk
of specific cancers. Until more is known about the specific components of diet that influence cancer risk, the best advice is to
consume a mostly plant-based diet that limits red and processed
meats and emphasizes a variety of vegetables, fruits, and whole
grains. A special emphasis should be placed on controlling total
caloric intake to help achieve and maintain a healthy weight.
3. Consume a healthy diet, with an emphasis on
plant foods.
4. If you drink alcoholic beverages, limit
consumption.
• Choose foods and beverages in amounts that help achieve
and maintain a healthy weight.
People who drink alcohol should limit their intake to no more
than two drinks per day for men and one drink per day for
women. Alcohol consumption is a risk factor for cancers of the
mouth, pharynx, larynx, esophagus, liver, colorectum, breast,
and possibly pancreas. For each of these cancers, risk increases
substantially with the intake of more than two drinks per day.
Even a few drinks per week may be associated with a slightly
increased risk of breast cancer in women. The mechanism for
how alcohol can affect breast cancer is not known with certainty, but it may be due to alcohol-induced increases in
circulating estrogen or other hormones in the blood or a direct
• Limit consumption of red and processed meat.
• Eat at least 2½ cups of vegetables and fruits each day.
• Choose whole grains instead of refined-grain products.
There is strong scientific evidence that healthy dietary patterns,
in combination with regular physical activity, are needed to
maintain a healthy body weight and to reduce cancer risk. Studies have shown that individuals who eat more processed and red
meat, potatoes, refined grains, and sugar-sweetened beverages
54 Cancer Facts & Figures 2014
effect of alcohol or its metabolites on breast tissue. Alcohol consumption combined with tobacco use increases the risk of
cancers of the mouth, larynx, and esophagus far more than
either drinking or smoking alone.
The American Cancer Society
Recommendations for Community Action
have outlined a variety of evidenced-based approaches in communities, worksites, and schools to halt and ultimately turn
around the obesity trends. Following are some specific
approaches recommended by the aforementioned groups that
are supported by the American Cancer Society and the American Cancer Society Cancer Action Network (ACS CAN), the
nonprofit, nonpartisan advocacy affiliate of the Society:
Many Americans encounter substantial barriers to consuming
healthy food and engaging in physical activity. Among those
barriers that have collectively contributed to increased obesity
are: limited access to affordable, healthy foods; increased portion sizes, especially of restaurant meals; marketing and
advertising of foods and beverages high in calories, fat, and
added sugar, particularly to kids; schools and worksites that are
not conducive to good health; community design that hinders
physical activity and promotes sedentary behavior; and economic and time constraints.
• Strengthen nutrition standards for all foods and beverages
sold or served to students in schools, both as part of school
meal programs and as competitive foods and beverages sold
outside of the programs.
The Society’s nutrition and physical activity guidelines include
Recommendations for Community Action because of the tremendous influence that the surrounding environment has on
individual food and activity choices. Acknowledging that reversing obesity trends will require extensive policy and
environmental changes, the Society calls for public, private, and
community organizations to create social and physical environments that support the adoption and maintenance of healthy
nutrition and physical activity behaviors to help people stay
well.
• Ensure that worksites have healthy food and beverage options
and that physical environments and workplace culture are
designed or adapted and maintained to facilitate physical
activity and weight control.
Achieving these Recommendations for Community Action will
require multiple strategies and bold action, ranging from the
implementation of community and workplace health promotion
programs to policies that affect community planning, transportation, school-based physical activity, and food services. The
Centers for Disease Control and Prevention (CDC), the Institute
of Medicine, the World Health Organization (WHO), and others
• Increase the quality and quantity of physical education and
the amount of time students are physically active in K-12
schools.
• Limit the availability, advertising, and marketing of foods
and beverages of low nutritional value, particularly in
schools.
• Provide calorie information on chain restaurant menus.
• Invest in community design that supports development of
sidewalks, bike lanes, and access to parks and green space.
The tobacco control experience has shown that policy and environmental changes at the national, state, and local levels are
critical to achieving changes in individual behavior. Measures
such as smoke-free laws and increases in cigarette excise taxes
have been highly effective in deterring tobacco use. To avert an
epidemic of obesity-related disease, similar purposeful changes
in public policy and in the community environment will be
required to help individuals make smart food and physical
activity choices and maintain a healthy body weight.
Environmental Cancer Risk
Two major classes of factors influence the incidence of cancer:
hereditary factors and acquired (environmental) factors. Hereditary factors come from our parents and cannot be modified.
Environmental factors, which include behavioral choices, are
potentially modifiable. These include tobacco use, poor nutrition, physical inactivity, obesity, certain infectious agents,
certain medical treatments, excessive sun exposure, and exposures to carcinogens (cancer-causing agents) that exist as
pollutants in our air, food, water, and soil. Some carcinogens
occur naturally, and some are created or concentrated by human
activity. For example, radon is a naturally occurring carcinogen
present in soil and rock; however, occupational radon exposure
occurs in underground mines, and substantial exposures also
occur in poorly ventilated basements in regions where radon soil
emissions are high.
Environmental factors (as opposed to hereditary factors)
account for an estimated 75%-80% of cancer cases and deaths in
the US. Exposure to carcinogenic agents in occupational, community, and other settings is thought to account for a relatively
small percentage of cancer deaths – about 4% from occupational
exposures and 2% from environmental pollutants (man-made
and naturally occurring). Although the estimated percentage of
cancers related to occupational and environmental carcinogens
is small compared to the cancer burden from tobacco smoking
Cancer Facts & Figures 2014 55
(30%) and the combination of poor nutrition, physical inactivity,
and obesity (35%), the relationship between such agents and
cancer is important for several reasons. First, even a small percentage of cancers can represent many deaths: 6% of cancer
deaths in the US in 2011 correspond to approximately 34,320
deaths. Second, the burden of exposure to occupational and
environmental carcinogens is borne disproportionately by
lower-income workers and communities, contributing to disparities in the cancer burden across the US population. Third,
although much is known about the relationship between occupational and environmental exposure and cancer, some
important research questions remain. These include the role of
exposures to certain classes of chemicals (such as hormonally
active agents) during critical periods of human development
and the potential for pollutants to interact with each other, as
well as with genetic and acquired factors.
How Environmental Carcinogens Are
Identified
The term carcinogen refers to exposures that can increase the
incidence of malignant tumors (cancer). The term can apply to a
single chemical such as benzene; fibrous minerals such as asbestos; metals and physical agents such as x-rays or ultraviolet light;
or exposures linked to specific occupations or industries (e.g.,
nickel refining). Carcinogens are usually identified on the basis
of epidemiological studies or by testing in animals. Studies of
occupational groups (cohorts) have played an important role in
understanding many chemical carcinogens – as well as radiation – because exposures are often higher among workers, who
can be followed for long periods of time. Some information has
also come from studies of persons exposed to carcinogens during medical treatments (such as radiation and estrogen), as well
as from studies conducted among individuals who experienced
high levels of short-term exposure to a chemical or physical
agent due to an accidental or intentional release (such as survivors of the atomic bomb explosions of Hiroshima and Nagasaki).
It is more difficult to study the relationship between exposure to
potentially carcinogenic substances and cancer risk in the general population because of uncertainties about exposure and
the challenge of long-term follow up. Moreover, relying upon epidemiological information to determine cancer risk does not
fulfill the public health goal of prevention since by the time the
increased risk is detected, a large number of people may have
been exposed.
Thus, for the past 40 years, the US and many other countries
have developed methods for identifying carcinogens through
animal testing using the “gold standard” of a 2-year or lifetime
bioassay in rodents. This test is expensive and time-consuming,
but it can provide information about potential carcinogens so
that human exposure can be reduced or eliminated. Many substances that are carcinogenic in rodent bioassays have not been
56 Cancer Facts & Figures 2014
adequately studied in humans, usually because an acceptable
study population has not been identified. Among the substances
that have proven carcinogenic in humans, all have shown positive results in animals when tested in well-conducted 2-year
bioassays.1 Between 25%-30% of established human carcinogens
were first identified through animal bioassays. Since animal
tests necessarily use high-dose exposures, human risk assessment usually requires extrapolation of the exposure-response
relationship observed in rodent bioassays to predict effects in
humans at lower doses. Typically, regulatory agencies in the US
and abroad have adopted the default assumption that no threshold level (level below which there is no increase in risk) of
exposure exists for carcinogenesis.
Evaluation of Carcinogens
The National Toxicology Program (NTP) plays an important role
in the identification and evaluation of carcinogens in the US,
and the International Agency for Research on Cancer (IARC)
plays a similar role internationally. The NTP was established in
1978 to coordinate toxicology testing programs within the federal government, including tests for carcinogenicity. The NTP is
also responsible for producing the Report on Carcinogens, an
informational scientific and public health document that identifies agents, substances, mixtures, or exposure circumstances
that may increase the risk of developing cancer.2 There are currently 107 agents classified by IARC as Group 1 (i.e., carcinogenic
to humans). For a list of substances included in the 11th Report
on Carcinogens that are known or reasonably anticipated to be
human carcinogens, see ntp.niehs.nih.gov/ntp/roc/toc11.html.
The IARC is a branch of the World Health Organization that regularly convenes scientific consensus groups to evaluate potential
carcinogens. After reviewing published data from laboratory,
animal, and human research, these committees reach consensus about whether the evidence should be designated “sufficient,”
“limited,” or “inadequate” to conclude that the substance is a
carcinogen. For a list of substances that have been reviewed by
the IARC monograph program, visit monographs.iarc.fr/ENG/
Classification/index.pdf. The American Cancer Society does not
have a formal program to systematically review and evaluate
carcinogens. However, information on selected topics can be
found at cancer.org.
Although the relatively small risks associated with low-level
exposure to carcinogens in air, food, or water are difficult to
detect in epidemiological studies, scientific and regulatory bodies worldwide have accepted the principle that it is reasonable
and prudent to reduce human exposure to substances shown to
be carcinogenic at higher levels of exposure. Although much
public concern about the influence of manmade pesticides and
industrial chemicals has focused on cancer, pollution may
adversely affect the health of humans and ecosystems in many
other ways. Research to understand the short- and long-term
impact of environmental pollutants on a broad range of outcomes, as well as regulatory actions to reduce exposure to
recognized hazards, has contributed to the protection of the
public and the preservation of the environment for future generations. It is important that this progress be recognized and
sustained. For more information on environmental cancer risks,
see the article published by Fontham et al. in CA: A Cancer Journal for Clinicians.3
References
1. Tomatis L, Melnick RL, Haseman J, et al. Alleged “misconceptions” distort perceptions of environmental cancer risks. FASEBJ. 2001; 15:195203.
2. US Department of Health and Human Services, National Toxicology
Program. 11th Report on Carcinogens. Research Triangle Park; 2005.
3. Fontham ET, Thun MJ, Ward E, et al. American Cancer Society perspectives on environmental factors and cancer. CA Cancer J Clin. 2009;
59:343351.
The Global Fight against Cancer
The ultimate mission of the American Cancer Society is to eliminate cancer as a major health problem. Because cancer knows
no boundaries, this mission extends around the world. Cancer is
an enormous global health burden, touching every region and
socioeconomic level. Today, cancer accounts for one in every
eight deaths worldwide – more than HIV/AIDS, tuberculosis,
and malaria combined. In 2012, there were an estimated 14.1
million cases of cancer diagnosed and 8.2 million deaths from
the disease around the world. More than 60 percent of all cancer
deaths occur in low- and middle-income countries, many of
which lack the medical resources and health systems to support
the disease burden. Moreover, the global cancer burden is growing at an alarming pace; in 2030 alone, about 21.7 million new
cancer cases and 13.0 million cancer deaths are expected to
occur, simply due to the growth and aging of the population. The
future burden may be further increased by the adoption of
behaviors and lifestyles associated with economic development
and urbanization (e.g., smoking, poor diet, physical inactivity,
and reproductive patterns) in low- and middle-income countries. Tobacco use is a major cause of the increasing global
burden of cancer as the number of smokers worldwide continues
to grow.
The first global public health treaty, the Framework Convention
on Tobacco Control (FCTC), was unanimously adopted by the
World Health Assembly on May 21, 2003, and subsequently
entered into force as a legally binding accord for all ratifying
states on February 27, 2005. The FCTC features specific provisions to control both the global supply and demand for tobacco,
including the regulation of tobacco product contents, packaging, labeling, advertising, promotion, sponsorship, taxation,
illicit trade, youth access, exposure to secondhand tobacco
smoke, and environmental and agricultural impacts. Parties to
the treaty are expected to strengthen national legislation, enact
effective tobacco control policies, and cooperate internationally
to reduce global tobacco consumption. A number of major
tobacco-producing nations, including Argentina, Indonesia,
Malawi, the US, and Zimbabwe, have either not signed or have
signed but not ratified the treaty.
Worldwide Tobacco Use
• The WHO estimates that 16% of the world’s population lives
in smoke-free environments.
Tobacco use is the most preventable cause of death worldwide,
and is responsible for the deaths of approximately half of longterm users.
• Tobacco use killed 100 million people in the 20th century and
will kill 1 billion people in the 21st century if current trends
continue.
• Each year, tobacco use is responsible for almost 6 million premature deaths, 80% of which are in low- and middle-income
countries; by 2030, this number is expected to increase to 8
million.
• Between 2002 and 2030, tobacco-attributable deaths are
expected to decrease by 9% in high-income countries, while
increasing by 100% (from 3.4 million to 6.8 million) in lowand middle-income countries.
• As of June 2013, out of 195 eligible countries, 177 have ratified
or acceded to the treaty, representing approximately 88% of
the world’s population.
• About one-third of the world’s population was covered by at
least one comprehensive tobacco control measure in 2012, up
from about 15% in 2008.
• Although tobacco tax increases are among the most costeffective tobacco control strategies, only 8% of the world
population is covered by comprehensive tobacco tax policy.
The Role of the American Cancer Society
With a century of experience in cancer control, the American
Cancer Society is uniquely positioned to help in leading the
global fight against cancer and tobacco by assisting and empowering the world’s cancer societies and anti-tobacco advocates.
The Society’s Global Health and Intramural Research departments are raising awareness about the growing global cancer
burden and promoting evidence-based cancer and tobacco control programs.
Cancer Facts & Figures 2014 57
The Society has established key focus areas to help reduce the
global burden of cancer, including global grassroots policy and
awareness, tobacco control, cancer screening and vaccination
for women and girls, and access to pain relief.
Make cancer control a political and public health priority.
Noncommunicable diseases (NCDs) such as cancer, heart disease, and diabetes account for about 65% of the world’s deaths.
Although 67% of these deaths occur in low- and middle-income
countries, less than 3% of private and public funding for health
is allocated to prevent and control NCDs in these areas. In September 2011, world leaders gathered at a special United Nations
High-level Meeting and adopted a Political Declaration that elevates cancer and other NCDs on the global health and
development agenda and includes key commitments to address
these diseases. In 2012, the decision-making body of the World
Health Organization (WHO) approved a resolution calling for a
25 percent reduction in premature deaths from NCDs by 2025
(also known as 25 by 25). This ambitious goal set the stage for the
adoption of: a comprehensive framework aimed at monitoring
NCD risk factors, such as smoking prevalence, and targets for
and indicators of increased access to breast and cervical cancer
screening, palliative care, and vaccination coverage. To maintain the momentum for making cancer and NCDS a global
priority, the Society collaborates with key partners, including
the NCD Alliance, the Union for International Cancer Control
(UICC), the American Heart Association, and the American Diabetes Association.
& Melinda Gates Foundation in 2010, the Society and its partners, the Africa Tobacco Control Alliance, the Framework
Convention Alliance, the Campaign for Tobacco-Free Kids, and
the International Union Against Tuberculosis and Lung Disease,
support and assist national governments and civil societies in
Africa to implement tobacco control policies such as advertising
bans, tobacco tax increases, graphic warning labels, and the
promotion of smoke-free environments.
Increase awareness about the global cancer burden. The
Society continues to work with global partners to increase
awareness about the growing global cancer and tobacco burdens and their impact on low- and middle-income countries. In
addition to print publications, the Society provides cancer information to millions of individuals throughout the world on its
Web site, cancer.org. More than 35% of the visitors to the Web
site come from outside the US. Information is currently available
in English, Spanish, Mandarin, and several other Asian languages, with plans to include more languages in the near future.
For more information on the global cancer burden, visit the
Society’s Global Health program Web site at cancer.org/international and global.cancer.org and see the following Intramural
Research program publications available on cancer.org and
tobaccoatlas.org:
Global Cancer Facts & Figures 2nd Edition
The Tobacco Atlas, Fourth Edition
The Cancer Atlas
Reduce tobacco use, with a particular focus on sub-Saharan
Africa. Through an $8 million (US) grant received from the Bill
The American Cancer Society
In 1913, 10 physicians and five laypeople founded the American
Society for the Control of Cancer. Its purpose was to raise awareness about cancer symptoms, treatment, and prevention; to
investigate what causes cancer; and to compile cancer statistics.
Later renamed the American Cancer Society, Inc., the organization now works with its more than 3 million volunteers to save
lives and create a world with less cancer and more birthdays by
helping people stay well, helping people get well, by working to
find cures, and by fighting back against the disease. A century
later, the Society is making remarkable progress in cancer prevention, early detection, treatment, and patient quality of life.
The overall cancer death rate has steadily declined since the
early 1990s, and the 5-year survival rate is now 68%, up from 49%
in the 1970s. Thanks to this progress, nearly 14 million cancer
survivors in the US will celebrate another birthday this year.
58 Cancer Facts & Figures 2014
How the American Cancer Society Is
Organized
The American Cancer Society, Inc., is a 501(c)(3) nonprofit corporation governed by a Board of Directors that sets policy, develops
and approves an enterprise-wide strategic plan and related
resource allocation, and is responsible for the performance of
the organization as a whole, with the advice and support of
regionally based volunteer boards.
The Society’s structure includes a central corporate office in
Atlanta, Georgia, regional offices supporting 11 geographic
Divisions, and more than 900 local offices in those regions. The
corporate office is responsible for overall strategic planning;
corporate support services such as human resources, financial
management, IT, etc.; development and implementation of
global and nationwide endeavors such as our groundbreaking
research program, our global program, and our 24-hour call
center; and provides technical support and materials to regional
and local offices for local delivery.
With a presence in more than 5,100 communities, the American
Cancer Society fights for every life threatened by every cancer in
every community. Our regional and local offices are organized
to engage communities in the cancer fight, delivering lifesaving
programs and services and raising money at the local level.
Offices are strategically placed around the country in an effort
to maximize the impact of our efforts, and to be as efficient as
possible with the money donated to the Society to fight cancer
and save lives.
Volunteers
As a global grassroots force, the Society relies on the strength of
more than 3 million dedicated volunteers. From leadership volunteers who set strategy and policy to members of the
community who organize special events, patient support, and
education programs, Society volunteers, supported by professional staff, drive every part of our mission. The Society’s vast
array of volunteer opportunities empowers people from every
community to play a role in saving lives, while they fulfill their
own.
How the American Cancer Society Saves Lives
The American Cancer Society is working relentlessly to saves
lives from cancer by helping people stay well and get well, by
finding cures, and by fighting back against the disease.
Helping People Stay Well
The American Cancer Society provides information that empowers people to take steps that help them prevent cancer or find it
early, when it is most treatable.
Prevention
The Quit For Life® Program is the nation’s leading tobacco cessation initiative, offered by 27 states and more than 675
employers and health plans throughout the US. Brought to you
by a collaboration between the American Cancer Society and
Alere Wellbeing, the program is built on the organizations’ 35
years of combined experience in tobacco cessation. The Quit For
Life Program employs an evidence-based combination of physical, psychological, and behavioral strategies to enable
participants to take responsibility for and overcome their addiction to tobacco. A critical mix of medication support,
phone-based cognitive behavioral coaching, text messaging,
Web-based learning and support tools produces an average quit
rate of 46 percent, making the program nine times more effective than quitting without support.
The Society offers many other programs to employers and other
systems to help their employees stay well and reduce their cancer risk, too. These include:
• The FreshStart® group-based tobacco cessation counseling
program, which is designed to help employees plan a successful quit attempt by providing essential information, skills for
coping with cravings, and group support
• Content subscription service, a free electronic tool kit
subscription offered by the Society to employers that support
the health and wellness needs of employees with information
about cancer prevention and early detection, and that support services and resources for those facing cancer
• HealthyLiving, a monthly electronic newsletter produced by
the American Cancer Society that teaches the importance of
making healthy lifestyle choices. The monthly e-newsletter
focuses on exercising, eating better, maintaining a healthy
weight, and avoiding the negative effects of stress. HealthyLiving is available in both English and Spanish, and the
content has been edited by the Society’s scientific staff to
ensure that the most up-to-date and accurate information is
being provided to employees.
• Assessment and consulting, which surveys a company’s
health and wellness policies and practices and recommends
evidence-based strategies that help improve employee
health behaviors, control health care costs, and increase
productivity
• The 10-week Active For LifeSM online program, which uses
individual and group goal-setting strategies to help employees become more physically active
• Tobacco Policy Planner, a free online assessment of company policies, benefits, and programs related to tobacco
control. After survey completion, the company receives an
automatic report highlighting where they are demonstrating
best practices and areas needing improvement. This customized report includes links to best practices and access to the
Society’s resources library to help plan the company’s next
steps.
Across the nation, the Society’s nonprofit, nonpartisan advocacy
affiliate, the American Cancer Society Cancer Action Network
(ACS CAN), works to create healthier communities by protecting people from the dangers of secondhand smoke. Today, 49% of
the US population is covered by a comprehensive smoke-free
workplace, restaurant, and bar law. In 2009, the Family Smoking
Prevention and Tobacco Control Act was signed into law. A
decade in the making, the law grants the US Food and Drug
Administration the authority to regulate the manufacturing,
selling, and marketing of tobacco products. Strong implementation of the law is vital to reducing death and disease from
tobacco products.
For the majority of Americans who do not smoke, the most
important ways to reduce cancer risk are to maintain a healthy
weight, be physically active on a regular basis, and eat a mostly
plant-based diet, consisting of a variety of vegetables and fruit,
Cancer Facts & Figures 2014 59
whole grains, and limited amounts of red and processed meats.
The Society publishes guidelines on nutrition and physical activity for cancer prevention in order to review the accumulating
scientific evidence on diet and cancer; to synthesize this evidence into clear, informative recommendations for the general
public; to promote healthy individual behaviors, as well as environments that support healthy eating and physical activity
habits; and, ultimately, to reduce cancer risk. These guidelines
form the foundation for the Society’s communication, worksite,
school, and community strategies designed to encourage and
support people in making healthy lifestyle behavior changes.
can help them locate a hospital, understand cancer and treatment options, learn what to expect and how to plan, help address
insurance concerns, find financial resources, find a local support group, and more. The Society can also help people who
speak languages other than English or Spanish find the assistance they need, offering services in 170 languages in total.
Early Detection
The Society also publishes a wide variety of pamphlets and
books that cover a multitude of topics, from patient education,
quality of life, and caregiving issues to healthy living. A complete
list of Society books is available for order at cancer.org/
bookstore.
Finding cancer at its earliest, most treatable stage gives patients
the greatest chance of survival. To help the public and health
care providers make informed decisions about cancer screening, the American Cancer Society publishes a variety of early
detection guidelines. These guidelines are assessed regularly to
ensure that recommendations are based on the most current
scientific evidence.
The Society currently provides screening guidelines for cancers
of the breast, cervix, colorectum, prostate, and endometrium,
and general recommendations for a cancer-related component
of a periodic checkup to examine the thyroid, mouth, skin,
lymph nodes, testicles, and ovaries.
Throughout its history, the Society has implemented a number
of aggressive awareness campaigns targeting the public and
health care professionals. Campaigns to increase usage of Pap
testing and mammography have contributed to a 70% decrease
in cervical cancer incidence rates since the introduction of the
Pap test in the 1950s and a 33% decline in breast cancer mortality rates since 1989. More recently, the Society launched
ambitious multimedia campaigns to encourage adults 50 years
of age and older to get tested for colorectal cancer. The Society
also continues to encourage the early detection of breast cancer
through public awareness and other efforts targeting poor and
underserved communities.
Helping People Get Well
For the nearly 1.7 million cancer patients diagnosed this year
and the approximately 14 million US cancer survivors, the
American Cancer Society is available anytime, day or night, to
offer free information, programs, services, and community
referrals to patients, survivors, and caregivers to help them
make decisions through every step of a cancer experience. These
resources are designed to help people facing cancer on their
journey to getting well.
Information, 24 Hours a Day, Seven Days a Week
The American Cancer Society is available 24 hours a day, seven
days a week online at cancer.org and by calling 1-800-227-2345.
Callers are connected with a Cancer Information Specialist who
60 Cancer Facts & Figures 2014
Information on every aspect of the cancer experience, from prevention to survivorship, is also available through the Society’s
Web site, cancer.org. The site contains in-depth information on
every major cancer type, as well as on treatments, side effects,
caregiving, and coping.
The Society publishes three peer-reviewed journals for health
care providers and researchers: Cancer, Cancer Cytopathology,
and CA: A Cancer Journal for Clinicians. More information about
the journals and their content can be found at acsjournals.com
Day-to-day Help and Emotional Support
The American Cancer Society can help cancer patients and their
families find the resources they need to make decisions about
the day-to-day challenges that can come from a cancer diagnosis, such as transportation to and from treatment, financial and
insurance needs, and lodging when having to travel away from
home for treatment. The Society also connects people with others who have been through similar experiences to offer emotional
support.
Help navigating the health care system: Learning how to navigate the cancer journey and the health care system can be
overwhelming for anyone, but it is particularly difficult for those
who are medically underserved, those who experience language
or health literacy barriers, or those with limited resources. The
American Cancer Society Patient Navigator Program was
designed to reach those most in need. The largest oncologyfocused patient navigator program in the country, it has specially
trained patient navigators at 123 cancer treatment facilities
across the nation. Patient navigators work in cooperation with
patients, family members, caregivers, and facility staff to connect patients with information, resources, and support to
decrease barriers and ultimately to improve health outcomes. In
2012, approximately 88,000 people relied on the Patient Navigator Program to help them through their diagnosis and treatment.
The Society collaborates with a variety of organizations, including the National Cancer Institute’s Center to Reduce Cancer
Health Disparities, the Center for Medicare and Medicaid Services, numerous cancer treatment centers, and others to
implement and evaluate this program.
Transportation to treatment: Cancer patients cite transportation to and from treatment as a critical need, second only to
direct financial assistance. The American Cancer Society Road
To Recovery® program matches these patients with specially
trained volunteer drivers. This program offers patients an additional key benefit of companionship and moral support during
the drive to medical appointments. In 2012, the American Cancer Society provided more than 1.48 million transportation
services to more than 81,000 constituents.
Lodging during treatment: When someone diagnosed with
cancer must travel away from home for the best treatment,
where to stay and how to afford accommodations are immediate
concerns and can sometimes affect treatment decisions. American Cancer Society Hope Lodge® facilities provide free, homelike,
temporary lodging for patients and their caregivers close to
treatment centers, thereby easing the emotional and financial
burden of finding affordable lodging. In 2012, the 31 Hope Lodge
locations provided approximately 261,000 nights of free lodging
to nearly 50,000 patients and caregivers – saving them more
than $27 million in lodging expenses. The American Cancer
Society also provided discounted lodging to many patients and
caregivers through arrangements with hotels in some communities without a Hope Lodge facility.
Breast cancer support: Through the American Cancer Society
Reach To Recovery® program, trained breast cancer survivor volunteers provide one-on-one support, information, and resource
referrals to people facing breast cancer. Patients are matched
with a volunteer who has had a similar breast cancer experience
as well as other similar characteristics. These volunteers will
meet one-on-one, either in person, by telephone, or via email,
with women anytime throughout their breast cancer
experience.
Cancer education classes: The I Can Cope® online educational
program is available free to people facing cancer and their families and friends. The program consists of self-paced classes that
can be taken anytime, day or night. People are welcome to take
as few or as many classes as they like. Among the topics offered
are information about cancer, managing treatments and side
effects, healthy eating during and after treatment, communicating with family and friends, finding resources, and more. The
classes are available at cancer.org/onlineclasses.
Hair-loss and mastectomy products: Some women wear wigs,
hats, breast forms, and special bras to help cope with the effects
of mastectomy and hair loss. The American Cancer Society’s
“tlc” Tender Loving Care® magazine/catalog offers informative
articles and a line of products to help women who are battling
cancer restore their appearance and self-esteem. The “tlc” products and catalogs may be ordered online at tlcdirect.org or by
calling 1-800-850-9445. All proceeds from product sales go back
into the Society’s programs and services for patients and
survivors.
Help with appearance-related side effects of treatment: The
Look Good Feel Better® program is a collaboration of the American Cancer Society, the Personal Care Products Council
Foundation, and the Professional Beauty Association that helps
women learn beauty techniques to restore their self-image and
cope with appearance-related side effects of cancer treatment.
This free program engages certified, licensed beauty professionals trained as Look Good Feel Better volunteers to provide tips
on makeup, skin care, nail care, and head coverings. Information and materials are also available for men and teens. To learn
more, visit the Look Good Feel Better Web site at lookgoodfeelbetter.org or call 1-800-395-LOOK (1-800-395-5665).
Finding hope and inspiration: People with cancer and their
loved ones do not have to face their cancer experience alone.
They can connect with others who want support through the
American Cancer Society Cancer Survivors Network® program.
Finding Cures
Research is at the heart of the American Cancer Society’s mission. For more than 65 years, the Society has been finding
answers that save lives – from changes in lifestyle to new
approaches in therapies to improving cancer patients’ quality of
life. No single nongovernmental, not-for-profit organization in
the US has invested more to find the causes and cures of cancer
than the Society. We relentlessly pursue the answers that help us
understand how to prevent, detect, and treat all cancer types.
We combine the world’s best and brightest researchers with the
world’s largest, oldest, and most effective community-based
anti-cancer organization to put answers into action.
The Society’s comprehensive research program consists of
extramural grants, as well as intramural programs in epidemiology, surveillance and health policy research, behavioral
research, international tobacco control research, and statistics
and evaluation. Intramural Research programs are led by the
Society’s own staff scientists.
Extramural Grants
The American Cancer Society’s extramural grants program supports research in a wide range of cancer-related disciplines at
more than 230 institutions. The Society is currently funding 982
research and training grants totaling approximately $492 million as of August 12, 2013. Grant applications are solicited
through a nationwide competition and are subjected to a rigorous external peer-review process, ensuring that only the most
promising research is funded. The Society primarily funds
investigators early in their research careers, at a time when they
are less likely to receive funding from the federal government,
thus giving the best and the brightest a chance to explore cutting-edge ideas at a time when they might not find funding
elsewhere. In addition to funding across the continuum of cancer research, from basic science to clinical and quality-of-life
research, the Society also focuses on needs that are unmet by
Cancer Facts & Figures 2014 61
other funding organizations. For instance, for 10 years, the Society supported a targeted research program to address the causes
of higher cancer mortality in the poor and medically underserved; this has recently become a priority area for funding.
To date, 47 Nobel Prize winners have received grant support
from the Society early in their careers, a number unmatched in
the nonprofit sector, and proof that the organization’s approach
to funding young researchers truly helps launch high-quality
scientific careers.
Intramural Research
For more than 65 years, the Society’s Intramural Research program has conducted and published high-quality epidemiologic
research to advance understanding of the causes and prevention of cancer and monitor and disseminate surveillance
information on cancer occurrence, risk factors, and screening.
Epidemiology
As a leader in cancer research, the Society’s Epidemiology
Research program has been conducting studies to identify factors that cause or prevent cancer since 1951. The first of these,
the Hammond-Horn Study, helped to establish cigarette smoking as a cause of death from lung cancer and coronary heart
disease, and also demonstrated the Society’s ability to conduct
very large prospective cohort studies. The Cancer Prevention
Study I (CPS-I) was launched in 1959 and included more than 1
million men and women recruited by 68,000 volunteers. Results
from CPS-I clearly demonstrated that the sharp increase in lung
cancer death rates among US men and women between 19591972 occurred only in smokers. Epidemiologic study of this
cohort was also among the first to show a relationship between
obesity and all-cause and cancer mortality.
In 1982, Cancer Prevention Study II (CPS-II) was established
through the recruitment of 1.2 million men and women by 77,000
volunteers. The more than 480,000 lifelong nonsmokers in CPSII provide the most stable estimates of lung cancer risk in the
absence of active smoking. CPS-II data are used extensively by
the Centers for Disease Control and Prevention (CDC) to estimate deaths attributable to smoking. The CPS-II study also
made important contributions in establishing the link between
obesity and cancer. A subgroup of CPS-II participants, the CPSII Nutrition Cohort has been particularly valuable for clarifying
associations of obesity, physical activity, diet, aspirin use, and
hormone use with cancer risk. Blood samples from this group
allow Society investigators and their collaborators at other institutions to study how genetic, hormonal, nutritional, and other
blood markers are related to cancer risk and/or progression.
The Cancer Prevention Studies have resulted in more than 500
scientific publications and have provided unique contributions
both within the Society and the global scientific community. In
addition to key contributions to the effects of the tobacco epi-
62 Cancer Facts & Figures 2014
demic over the past half-century, other important findings from
these studies include:
• The association of obesity with increased death rates for at
least 10 cancer sites, including colon and postmenopausal
breast cancer
• The link between aspirin use and lower risk of colon cancer,
opening the door to research on chronic inflammation and
cancer
• The relationship between cancer and certain potentially
modifiable factors, such as physical inactivity, prolonged
hormone use, and certain dietary factors
• The association between air pollution, especially small particulates and ozone, with increased death rates from heart
and lung conditions, which helped to motivate the Environmental Protection Agency to propose more stringent limits
on air pollution
While landmark findings from the CPS-II Nutrition Cohort have
informed multiple areas of public health policy and clinical
practice, the cohort is aging. A new cohort is needed to explore
the effects of changing exposures and to provide greater opportunity to integrate biological measurements into studies of
genetic and environmental risk factors. In 2006, Society epidemiologists began the enrollment of a new cohort, CPS-3, with
the goal of recruiting and following approximately 300,000 men
and women. All participants are providing blood samples at the
time of enrollment. Following on the long history of partnering
with Society volunteers and supporters for establishing a cohort,
the Society’s community-based Relay For Life® events are one of
the primary venues for recruiting and enrolling participants.
Although similar large cohorts are being established in Canada
and some European and Asian countries, there are currently no
nationwide studies of this magnitude; therefore, the data collected from CPS-3 participants will provide unique opportunities
for research in the US.
Surveillance & Health Services Research
Through the Surveillance Research program, the Society disseminates the most current cancer statistics in CA: A Cancer
Journal for Clinicians (caonline.amcancersoc.org), as well as
eight Cancer Facts & Figures publications. These publications
are the most widely cited sources for cancer statistics and are
available in hard copy from Society Division offices and online
through the Society’s Web site at cancer.org/statistics. Society
scientists also monitor trends in cancer risk factors and screening and publish these results annually – along with Society
recommendations, policy initiatives, and evidence-based programs – in Cancer Prevention & Early Detection Facts & Figures.
Surveillance Research also collaborates with the International
Agency for Research on Cancer (IARC) to publish Global Cancer
Facts & Figures, an inter-national companion to Cancer Facts &
Figures.
Since 1998, the Society has collaborated with the National Cancer Institute, the Centers for Disease Control and Prevention, the
National Center for Health Statistics, and the North American
Association of Central Cancer Registries to produce the Annual
Report to the Nation on the Status of Cancer, a peer-reviewed
journal article that reports current information related to cancer rates and trends in the US.
Epidemiologists in Surveillance Research also conduct and publish high-quality epidemiologic research in order to advance the
understanding of cancer. Research topics include exploring
socioeconomic, racial, and geographic cancer disparities,
describing global cancer trends, and demonstrating the association between public health interventions, such as tobacco
control, and cancer incidence and mortality. Recent studies
have focused on declines in colorectal cancer incidence in relation to increased colonoscopy screening, differences in cigarette
affordability by state, and disparities in trends of pancreatic
cancer death rates in the US.
Interest in developing a Health Services Research (HSR) program within the American Cancer Society’s Intramural Research
program began in the late 1990s, motivated by increasing disparities in the quality and outcomes of cancer care. The primary
objective of the HSR program is to perform high-quality, highimpact research to evaluate disparities in cancer treatment and
outcomes and support the Society’s mission and program initiatives. To accomplish its objectives, the HSR program’s work has
primarily involved the use of secondary data sources. The
National Cancer Data Base (NCDB), jointly sponsored by the
American Cancer Society and the American College of Surgeons,
has been key to the HSR program’s research on the impact of
insurance on cancer status, treatments, and outcomes, as well
as for broader surveillance of cancer incidence/prevalence and
treatment patterns. Other databases used to support the HSR
program’s objectives include linked SEER-Medicare data, linked
state registry and Medicaid enrollment data, and Medical
Expenditure Panel Survey Data linked with National Health
Interview Survey Data. Recent studies include disparities in the
stage at diagnosis for testicular cancer and a comparison of case
coverage between the NCDB and population-based cancer
registries.
Economic and Health Policy Research
The predecessor of the Economic and Health Policy Research
program (EHPR), the International Tobacco Control Research
program (ITCR), was created in 2006 to support collaborative
tobacco control efforts involving the Society and numerous
international organizations and academic institutions such as
the WHO Tobacco Free Initiative, the Centers for Disease Control and Prevention (CDC), the Campaign for Tobacco Free Kids,
the Johns Hopkins University, and the University of Illinois,
among others. The ITCR focused on economic and policy
research in tobacco control and research capacity building for
the collection and analysis of economic data to provide the evidence base for tobacco control in low- and middle- income
countries. This was an important investment by the Society
since the economic forces and economic tobacco control measures are major factors in driving and containing the global
tobacco epidemic. Major donors in global health such as the
Bloomberg Philanthropies, the Bill & Melinda Gates Foundation, and the National Institutes of Health supported this effort
by granting the ITCR additional funding.
The most important service publication of the ITCRP is The
Tobacco Atlas, which is produced in collaboration with the Society’s Global Health department, Georgia State University, and
the World Lung Foundation. The Tobacco Atlas, Fourth Edition
(tobaccoatlas.org) was released at the 15th World Conference on
Tobacco or Health in 2012 in Singapore and has been translated
to four other languages – French, Spanish, Mandarin, and
Arabic.
Due to the high demand for the type of analysis generated by the
ITCR, the Society’s leadership made a strategic decision in early
2013 to expand the program to the area of obesity, nutrition and
physical activity and change the name of the program to Economic and Health Policy Research.
Behavioral Research Center
The American Cancer Society was one of the first organizations
to recognize the importance of behavioral and psychosocial factors in the prevention and control of cancer and to fund
extramural research in this area. In 1995, the Society established
the Behavioral Research Center (BRC) as an intramural department. The BRC’s work currently focuses on cancer survivorship,
quality of life, and tobacco research. It also addresses the issues
of underserved and disadvantaged populations, including
racial/ethnic minorities, rural, low-income, and aging populations. The BRC’s ongoing projects include:
• Studies of the quality of life of cancer survivors, which include
a nationwide longitudinal study of a cohort of more than
3,000 cancer survivors that explores the physical and psychosocial adjustment to cancer and identifies factors affecting
quality of life. Results from this research have informed the
Society’s informational materials and support programs for
cancer patients, survivors, and their loved ones.
• A study of side effects of cancer treatment such as pain,
fatigue or depression, which often go under-reported or
undertreated. Data from this collaboration between the Society, the National Cancer Institute, and the American College
of Surgeons could play an important role in improving symptom control, which would ultimately lead to improvements in
quality of life, functioning, and treatment adherence.
• Studies to identify and prioritize gaps in information and
resources for cancer survivors as they transition from active
treatment under the care of the oncology team back to the
Cancer Facts & Figures 2014 63
community care setting. Research results will inform interventions by the Society and others by describing the issues
cancer survivors continue to face after their treatment ends,
the key variables interventions should target, and the best
time to intervene.
• Studies of family caregivers that explore the impact of the
family’s involvement in cancer care on the quality of life of the
cancer survivor and the caregiver
• Studies investigating how social, psychological, and other factors impact smokers’ motivation and ability to quit in order
to improve existing Society programs for smoking cessation
(e.g., FreshStart, Great American Smokeout®) or to develop
new technology-based interventions for smokers who seek
cessation assistance
• Contributions to the development of a National Cancer Survivorship Resource Center meant to advance survivorship as
a distinct phase of cancer care, promote healthy behaviors to
reduce long-term and late effects of cancer and its treatment,
and improve surveillance and screening practices to detect
the return of cancer
• Research to better understand cancer prevention and control
behavior in underserved populations and identify effective
strategies for connecting individuals with cancer control
needs to information, programs, and services
Statistics and Evaluation Center
The mission of the Statistics and Evaluation Center (SEC) is to
deliver valid, reliable, accurate, and timely information to American Cancer Society staff for evidence-based decision making
that ensures the Society continues to provide effective, highquality programs. Staffed by professional statisticians and
evaluators, the SEC has three main responsibilities: 1) to provide
leadership on evaluations of Society mission and income delivery programs, including study design, data analysis, and report
preparation; 2) to provide operational support for surveys and
other data collection related to Society constituents and consumers; and 3) to support the broader Society mission through
information integration, including mapping and return on
investment studies. SEC expertise and assistance are available
to Society staff at the Corporate Center and across the
Divisions.
SEC staff design and conduct process and outcome evaluations
of Society programs, projects, and initiatives; focus groups;
structured/semi-structured interviews; and needs assessments.
All evaluations are logic model driven. Since 2006, the SEC, the
Behavioral Research Center, Health Promotions and Cancer
Control Sciences have worked together on the Integrated Evaluation Team, which has coordinated a systematic evaluation of
all Society survivorship and quality of life programs.
The SEC is currently engaged in evaluating the Society’s externally funded community-based cancer prevention initiatives, its
Cancer Survivors Network online community, its health profes64 Cancer Facts & Figures 2014
sional training grant program, and an online self-help program
for cancer survivors. SEC staff are active participants in transformation discussions, especially those related to metrics and
evaluation. They also are part of the effort to develop guidelines
for programs that support cancer survivors. All of these studies
are focused on improving the Society’s mission and income
delivery programs.
Fighting Back
Conquering cancer is as much a matter of public policy as scientific discovery. Whether it’s advocating for quality, affordable
health care for all Americans, increasing funding for cancer
research and programs, improving quality of life for patients
and their families, or enacting laws and policies that help
decrease tobacco use, lawmakers play a critical role in determining how much progress we make as a country to defeat
cancer. The American Cancer Society Cancer Action Network
(ACS CAN), the Society’s nonprofit, nonpartisan advocacy affiliate, uses applied policy analysis, direct lobbying, grassroots
action, and media advocacy to ensure elected officials nationwide pass laws that help save lives from cancer.
Created in 2001, ACS CAN is the force behind a powerful grassroots movement uniting and empowering cancer patients,
survivors, caregivers, and their families to fight back against
cancer. The nation’s leading voice advocating for public policies
that are helping to defeat cancer, ACS CAN works to encourage
elected officials and candidates to make the fight against cancer
a top national priority. In recent years, ACS CAN has worked to
pass laws at the federal, state, and local levels focused on increasing funding for groundbreaking cancer research; improving
access to proven prevention and early detection measures, treatment, and follow-up care; and improving quality of life for cancer
patients. Some recent advocacy accomplishments impacting
cancer patients include:
• Continued implementation of the Affordable Care Act (ACA)
of 2010, which includes numerous provisions that help people
with cancer and their families access lifesaving care. The
law’s patient protections ensure that:
·· Cancer patients are no longer denied health coverage
because of a preexisting condition.
·· People with cancer are no longer charged more for coverage because of their health status.
·· Health coverage can no longer be rescinded just because
someone gets sick.
·· Health plans no longer include annual and lifetime dollar
limits on coverage.
·· Children and young adults can be covered under their
parents’ health plan until they turn 26.
·· Most health plans are required to cover essential benefits
needed to prevent, treat, and survive a serious disease such
as cancer.
·· Patients who take part in clinical trials are still covered for
routine care.
·· Patients receive proven preventive care, including breast,
cervical, and colorectal cancer screening and smoking cessation treatment, at no cost to them.
The law also refocuses the health care system on disease prevention by calling for the creation of a national prevention strategy
and establishing a Prevention and Public Health Fund to support successful prevention programs in communities
nationwide. In addition, the law provides federal funds to states
that choose to expand access to health coverage for the uninsured through Medicaid. Please refer to acscan.org/healthcare
for more information.
• Supporting legislation that focuses on preventing cancer by
reducing tobacco use, obesity prevalence, and tanning bed
use by minors; improving nutrition; and increasing physical
activity. By successfully working with partners, ACS CAN
helped pass a law that gave the FDA authority to regulate the
production and marketing of tobacco products.
• Helped pass comprehensive smoke-free laws in 24 states
and the District of Columbia, Puerto Rico, and the US Virgin
Islands that require all workplaces, restaurants, and bars to
be smoke-free, covering nearly half of the US population, and
defended these laws in court
• Helped increase taxes on tobacco products to an average
state cigarette tax of $1.53 per pack and defended against tax
rollbacks
• Continued its role as intervener in the US government’s
lawsuit against the tobacco industry, in which manufacturers
have been convicted as racketeers for decades of fraud associated with marketing of tobacco products
• Continued implementation of the Healthy, Hunger-Free Kids
Act of 2010, strong legislation to reauthorize the federal child
nutrition programs and strengthen school nutrition. The
law improves nutrition standards and increases funding for
school meals, establishes nutrition standards for foods sold in
schools outside of meal programs, and strengthens local wellness policies by providing resources and technical assistance
for their implementation and requiring them to be publicly
available and periodically reviewed.
• Advocated for state requirements for increased quality physical education in all schools
• Supported the federal government’s development of voluntary
nutrition standards for foods marketed to children
• Worked with state governments to implement laws prohibiting tanning bed use for everyone under the age of 18
• Worked to improve access to essential cancer screening
services, especially among low-income, uninsured, and
underinsured populations
• Advocated for full funding for the National Breast and Cervical Cancer Early Detection Program (NBCCEDP), which
provides free breast and cervical cancer screenings and treatment to low-income, uninsured, and medically underserved
women
• Advocated for legislation to create a new nationwide
colorectal screening and treatment program modeled after
NBCCEDP
• Improved quality of life for cancer patients by advocating for
patients and survivors to receive the best cancer care that
matches treatments to patient and family goals across their
life course. ACS CAN has:
·· Advocated for balanced pain policies in multiple states and
at the federal level to ensure patients and survivors have
continued access to the treatments that promote better
pain management and improved quality of life
·· Advanced a new quality-of-life legislative platform that
addresses the need for better patient access to palliative care services that address patient symptoms such as
pain and fatigue that begins at point of diagnosis and is
provided alongside curative treatment, as well as expand
research funding in this area and build the workforce of
the health professions needed to provide patients with
serious illnesses better patient-centered, coordinated care.
Increased public awareness of the increasingly urgent cancer drug shortage problem and advocated for solutions to
the complex, multiple causes of cancer drug shortages
Some efforts in the fight against cancer are more visible than
others, but each successful battle is an important contribution
to what will ultimately be victory over the disease. ACS CAN is
making sure the voice of the cancer community is heard in the
halls of government and is empowering communities everywhere to fight back.
The Society is also rallying people to fight back against the disease through our Relay For Life® and Making Strides Against
Breast Cancer® programs. As the world’s largest movement to
finish the fight against cancer, the Relay For Life program brings
communities together across the globe to celebrate cancer survivors, remember loved ones lost, and fight back against a
disease that has taken too much. At Relay events, teams of people camp out at a local high school, park, or fairground and take
turns walking or running around track or path for up to 24
hours. The Making Strides Against Breast Cancer program is the
largest network of breast cancer awareness events in the nation,
uniting communities across the United States to fund the fight
against the disease. Every event is a powerful and inspiring
opportunity to honor people who have battled breast cancer,
raise awareness about the disease, and raise funds to help the
Society fight it with research, information, and services, and
access to mammograms for women who need them.
Cancer Facts & Figures 2014 65
Sources of Statistics
Estimated new cancer cases in 2014. The number of new US
cancer cases in the US in 2014 was projected using a spatiotemporal model based on incidence data from 49 states and the
District of Columbia for the years 1995-2010 that met the North
American Association of Central Cancer Registries’ (NAACCR)
high-quality data standard for incidence. This method considers
geographic variations in sociodemographic and lifestyle factors,
medical settings, and cancer screening behaviors as predictors
of incidence, and also accounts for expected delays in case
reporting. (For more information on the estimation of new cases,
see “A” in Additional information on page 67.)
Incidence rates. Incidence rates are defined as the number of
people per 100,000 who are diagnosed with cancer during a
given time period. Incidence rates in this publication are age
adjusted to the 2000 US standard population to allow comparisons across populations with different age distributions. State-,
race-, and ethnicity-specific incidence rates were previously
published in NAACCR’s publication Cancer Incidence in North
America, 2006-2010. (See “B” in Additional information on page
67 for full reference.)
Trends in cancer incidence provided in the Selected Cancers section of this publication are based on incidence data reported to
the 13 oldest Surveillance, Epidemiology, and End Results (SEER)
registries, representing approximately 14% of the US population,
and were adjusted for delays in reporting. Delay-adjustment
accounts for delays and error corrections that occur in the
reporting of cancer cases. Incidence rates that are not adjusted
for delays in reporting underestimate the number of cancer
cases in the most recent time period. Cancer rates most affected
by reporting delays are melanoma of the skin, leukemia, and
prostate because these cancers are frequently diagnosed in nonhospital settings. These trends were originally published in the
SEER Cancer Statistics Review (CSR) 1975-2010. (See “C” in Additional information on page 67 for full reference).
Estimated cancer deaths in 2014. The estimated number of US
cancer deaths in the US was calculated by fitting the number of
cancer deaths from 1995 to 2010 to a statistical model that forecasts the number of deaths expected to occur in 2014. The
estimated number of cancer deaths for each state is calculated
similarly, using state-level data. For both US and state estimates,
data on the number of deaths are obtained from the National
Center for Health Statistics (NCHS) at the Centers for Disease
Control and Prevention. (For more information on this method,
see “D” in Additional information on page 67.)
Mortality rates. Mortality rates, or death rates, are defined as
the number of people per 100,000 dying of a disease during a
given year. In this publication, mortality rates are based on
66 Cancer Facts & Figures 2014
counts of cancer deaths compiled by NCHS and population data
from the US Census Bureau. Death rates in this publication are
age adjusted to the 2000 US standard population to allow comparisons across populations with different age distributions.
These rates should be compared only to other statistics that are
age adjusted to the US 2000 standard population. Trends in cancer mortality rates provided for selected cancer sites were based
on mortality data from 1992 to 2010 and were first published in
the CSR 1975-2010. (See “C” in Additional information for full reference on page 67.)
Important note about estimated cancer cases and deaths
for the current year. The estimated number of new cancer
cases and deaths in the current year is model-based and may
produce numbers that vary considerably from year to year for
reasons other than changes in cancer occurrence. For this reason, the use of our estimates to track year-to-year changes in
cancer occurrence or deaths is strongly discouraged. Ageadjusted incidence and mortality rates reported by the SEER
program and NCHS, respectively, are the suggested statistics to
use when tracking cancer trends for the US. Rates from state
cancer registries are useful for tracking local trends.
Survival. This report presents relative survival rates to describe
cancer survival. Relative survival adjusts for normal life expectancy by comparing survival among cancer patients to that of
people not diagnosed with cancer who are of the same age, race,
and sex. Five-year survival statistics presented in this publication were originally published in CSR 1975-2010 and are for
diagnosis years 2003 to 2009, with all patients followed through
2010. In addition to 5-year relative survival rates, 1-, 10-, and
15-year survival rates are presented for selected cancer sites.
These survival statistics are generated using the National Cancer Institute’s SEER 18 database and SEER*Stat software version
8.0.4. (See “E” in Additional information for full references.) Oneyear survival rates were based on cancer patients diagnosed
from 2005 to 2009, 10-year survival rates were based on diagnoses from 1997 to 2009, and 15-year survival rates were based on
diagnoses from 1992 to 2009; all patients were followed through
2010.
Probability of developing cancer. Probabilities of developing
cancer were calculated using DevCan (Probability of Developing
Cancer) software version 6.7.0, developed by the National Cancer
Institute. (See “F” in Additional information for full reference.)
These probabilities reflect the average experience of people in
the US and do not take into account individual behaviors and
risk factors. For example, the estimate of 1 man in 13 developing
lung cancer in a lifetime underestimates the risk for smokers
and overestimates the risk for nonsmokers.
Additional information. More information on the methods
used to generate the statistics for this report can be found in the
following publications:
A. Zhu L, Pickle LW, Naishadham D, et al. Predicting US and state-level
cancer counts for the current calendar year: part II – evaluation of
spatio-temporal projection methods for incidence. Cancer 2012;118(4):
1100-9.
B. Copeland G, Lake A, Firth R, et al. (eds). Cancer in North America:
2006-2010. Volume Two: Registry-specific Cancer Incidence in the United
States and Canada. Springfield, IL: North American Association of
Cen¬tral Cancer Registries, Inc. May 2013. Available at naaccr.org/
Dataand¬Publications/CINAPubs.aspx.
C. Howlader N, Noone AM, Krapcho M, et al. (eds). SEER Cancer Statistics Review, 1975-2010. National Cancer Institute. Bethesda, MD, 2013.
Avail¬able at seer.cancer.gov.
D. Chen HS, Portier K, Ghosh K, et al. Predicting US and State-level
counts for the current calendar year: part I – evaluation of temporal
projection methods for mortality. Cancer 2012;118(4):1091-9.
E. SEER 18 database: Surveillance, Epidemiology, and End Results
(SEER) Program (www.seer.cancer.gov) SEER*Stat Database: Incidence
– SEER 18 Regs Research Data + Hurricane Katrina Impacted Louisiana
Cases, Nov 2012 Sub (1973-2010 varying) – Linked To County Attributes
– Total U.S., 1969-2011 Counties, National Cancer Institute, DCCPS, Surveillance Research Program, Cancer Statistics Branch, released April
2013, based on the November 2012 submission. SEER*Stat software:
Surveillance Research Program, National Cancer Institute SEER*Stat
software (www.seer.cancer.gov/seerstat) version 8.0.4.
F. DevCan: Probability of Developing or Dying of Cancer Software, Version 6.7.0; Statistical Research and Applications Branch, National Cancer Institute, April 2013. http://srab.cancer.gov/devcan
Cancer Facts & Figures 2014 67
Screening Guidelines for the Early Detection of Cancer in Average-risk
Asymptomatic People
Cancer Site
Population
Test or Procedure
Frequency
Breast
Women,
ages 20+
Breast self-examination
(BSE)
It is acceptable for women to choose not to do BSE or to do BSE regularly (monthly) or
irregularly. Beginning in their early 20s, women should be told about the benefits and
limitations of BSE. Whether or not a woman ever performs BSE, the importance of prompt
reporting of any new breast symptoms to a health professional should be emphasized.
Women who choose to do BSE should receive instruction and have their technique reviewed
on the occasion of a periodic health examination.
Clinical breast examination
(CBE)
For women in their 20s and 30s, it is recommended that CBE be part of a periodic health
examination, preferably at least every three years. Asymptomatic women ages 40 and
over should continue to receive a CBE as part of a periodic health examination, preferably
annually.
Mammography
Begin annual mammography at age 40.*
Cervix†
Women,
ages 21-65
Pap test &
HPV DNA test
Cervical cancer screening should begin at age 21. For women ages 21-29, screening should
be done every 3 years with conventional or liquid-based Pap tests. For women ages 30-65,
screening should be done every 5 years with both the HPV test and the Pap test (preferred),
or every 3 years with the Pap test alone (acceptable). Women ages 65+ who have had ≥3
consecutive negative Pap tests or ≥2 consecutive negative HPV and Pap tests within the past
10 years, with the most recent test occurring within 5 years, and women who have had a
total hysterectomy should stop cervical cancer screening. Women should not be screened
annually by any method at any age.
Colorectal
Men and
women,
ages 50+
Fecal occult blood test
(FOBT) with at least 50%
test sensitivity for cancer, or
fecal immunochemical test
(FIT) with at least 50% test
sensitivity for cancer, or
Annual, starting at age 50. Testing at home with adherence to manufacturer’s recommendation
for collection techniques and number of samples is recommended. FOBT with the single
stool sample collected on the clinician’s fingertip during a digital rectal examination is not
recommended. Guaiac-based toilet bowl FOBT tests also are not recommended. In comparison
with guaiac-based tests for the detection of occult blood, immunochemical tests are more
patient-friendly, and are likely to be equal or better in sensitivity and specificity. There is no
justification for repeating FOBT in response to an initial positive finding.
Stool DNA test**, or
Interval uncertain, starting at age 50
Flexible sigmoidoscopy
(FSIG), or
Every 5 years, starting at age 50. FSIG can be performed alone, or consideration can be
given to combining FSIG performed every 5 years with a highly sensitive gFOBT or FIT
performed annually.
Double contrast barium
enema (DCBE), or
Every 5 years, starting at age 50
Colonoscopy
Every 10 years, starting at age 50
CT Colonography
Every 5 years, starting at age 50
Endometrial
Women, at
menopause
Lung
Low-dose helical CT
Current or
former smokers (LDCT)
ages 55-74 in
good health
with at least a
30 pack-year
history
Clinicians with access to high-volume, high-quality lung cancer screening and treatment
centers should initiate a discussion about lung cancer screening with apparently healthy
patients ages 55-74 who have at least a 30 pack-year smoking history, and who currently
smoke or have quit within the past 15 years. A process of informed and shared decision
making with a clinician related to the potential benefits, limitations, and harms associated with
screening for lung cancer with LDCT should occur before any decision is made to initiate
lung cancer screening. Smoking cessation counseling remains a high priority for clinical
attention in discussions with current smokers, who should be informed of their continuing
risk of lung cancer. Screening should not be viewed as an alternative to smoking cessation
Prostate
Men,
ages 50+
Digital rectal examination
(DRE) and prostate-specific
antigen test (PSA)
Men who have at least a 10-year life expectancy should have an opportunity to make an
informed decision with their health care provider about whether to be screened for prostate
cancer, after receiving information about the potential benefits, risks, and uncertainties
associated with prostate cancer screening. Prostate cancer screening should not occur
without an informed decision-making process.
Cancerrelated
checkup
Men and
women,
ages 20+
On the occasion of a periodic health examination, the cancer-related checkup should include examination for cancers of
the thyroid, testicles, ovaries, lymph nodes, oral cavity, and skin, as well as health counseling about tobacco, sun exposure,
diet and nutrition, risk factors, sexual practices, and environmental and occupational exposures.
At the time of menopause, women at average risk should be informed about risks and symptoms of endometrial cancer
and strongly encouraged to report any unexpected bleeding or spotting to their physicians.
*Beginning at age 40, annual clinical breast examination should be performed prior to mammography. **The stool DNA test approved for colorectal cancer screening
in 2008 is no longer commercially available. New stool DNA tests are presently undergoing evaluation.
68 Cancer Facts & Figures 2014
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Acknowledgments
The production of this report would not have been possible without the efforts of: Terri Ades, DNP, FNP-BC;
Rick Alteri, MD; Cammie Barnes, MBA; Tracie Bertaut, APR; Sarah Bogdan; Durado Brooks, MD, MPH; Greta
Bunin, PhD; William Chambers, PhD; Carol DeSantis, MPH; Ted Gansler, MD, MBA; Sue Gapstur, PhD; Kerri
Grober; Annemarie Henning, MFA; Angela Jones; Rebecca Kirch, JD; Joan Kramer, MD; Alex Liber, MPH;
Joannie Lortet-Tieulent, MSc; Jiemin Ma, PhD; Cathy Magliarditi; Anthony Piercy; Melissa Maitin-Shepard,
MPP; Anna Meadows, MD; Ken Portier, PhD; Cheri Richard, MS; Anthony Robbins, MD, PhD; Hana Ross, PhD;
David Sampson; Debbie Saslow, PhD; Mona Shah, MPH; Edgar Simard, PhD, MPH; Scott Simpson; Robert
Smith, PhD; Kirsten Sloan; Kevin Stein, PhD; Michal Stoklosa, MA; Kristen Sullivan, MS, MPH; Marie Thornsberry; Lindsey Torre, MPH; Elizabeth Ward, PhD; Martin Weinstock, MD; and Joe Zou.
Cancer Facts & Figures is an annual publication of the American Cancer Society, Atlanta, Georgia.
For more information, contact:
Rebecca Siegel, MPH; Ahmedin Jemal, DVM, PhD
Surveillance and Health Services Research Program
©2014, American Cancer Society, Inc.
No. 500814